H2020 STRATOFLY PROJECT: FROM EUROPE TO AUSTRALIA IN LESS THAN 3 HOURS

N. Viola; R. Fusaro; Davide Ferretto; Oscar Gori; Bayindir Saracoglu; Ali Can Ispir; Christophe Schram; Volker Grewe; Johannes Friedrich Plezer; Jan Martinez; Marco Marini; L. Cutrone; G. Saccone; Santiago Hernandez; Karel Lammers; Axel Vincent; Didier Hauglustaine; Bernd Liebhardt; Florian Linke; Daniel Bodmer; Thommie Nilsson; Christer Fureby; Christian Ibron

H2020 STRATOFLY PROJECT: FROM EUROPE TO AUSTRALIA IN LESS THAN 3 HOURS

N. Viola, R. Fusaro, Davide Ferretto, Oscar Gori, Bayindir Saracoglu, Ali Can Ispir, Christophe Schram, Volker Grewe, Johannes Friedrich Plezer, Jan Martinez, Marco Marini, L. Cutrone, G. Saccone, Santiago Hernandez, Karel Lammers, Axel Vincent, Didier Hauglustaine, Bernd Liebhardt, Florian Linke, Daniel BodmerThommie Nilsson, Christer Fureby, Christian Ibron

Heat Transfer

Research output: Chapter in Book/Report/Conference proceeding › Paper in conference proceeding › peer-review

Abstract

As eluded in previous studies, with special reference to those carried out in the European framework, some innovative high-speed aircraft configurations have now the potential to assure an economically viable high-speed aircraft fleet. They make use of unexploited flight routes in the stratosphere, offering a solution to the presently congested flight paths while ensuring a minimum environmental impact in terms of emitted noise and green-house gases, particularly during stratospheric cruise. However, only a dedicated multi-disciplinary integrated design approach could realize this, by considering airframe architectures embedding the propulsion systems as well as meticulously integrating crucial subsystems. In this context, starting from an in-depth investigation of the current status of the activities, the STRATOFLY project has been funded by the European Commission, under the framework of Horizon 2020 plan, with the aim of assessing the potential of this type of high-speed transport vehicle to reach Technology Readiness Level (TRL) 6 by 2035, with respect to key technological, societal and economical aspects. This paper aims at summarizing the main results achieved so far to solve the main issues related to thermal and structural integrity, low-emissions combined propulsion cycles, subsystems design and integration, including smart energy management, environmental aspects impacting climate change, noise emissions and social acceptance, and economic viability accounting for safety and human factors.

Original language	English
Title of host publication	32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021
Publisher	International Council of the Aeronautical Sciences
ISBN (Electronic)	9783932182914
Publication status	Published - 2021
Event	32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021 - Shanghai, China Duration: 2021 Sept 6 → 2021 Sept 10

Conference

Conference	32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021
Country/Territory	China
City	Shanghai
Period	2021/09/06 → 2021/09/10

Subject classification (UKÄ)

Vehicle and Aerospace Engineering
Energy Engineering

Free keywords

Environmental sustainability
High-speed transportation
Technological challenges

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Cite this

Viola, N., Fusaro, R., Ferretto, D., Gori, O., Saracoglu, B., Ispir, A. C., Schram, C., Grewe, V., Plezer, J. F., Martinez, J., Marini, M., Cutrone, L., Saccone, G., Hernandez, S., Lammers, K., Vincent, A., Hauglustaine, D., Liebhardt, B., Linke, F., ... Ibron, C. (2021). H2020 STRATOFLY PROJECT: FROM EUROPE TO AUSTRALIA IN LESS THAN 3 HOURS. In 32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021 International Council of the Aeronautical Sciences.

@inproceedings{618d1c5207ba49e8b809b038d89ea218,

title = "H2020 STRATOFLY PROJECT: FROM EUROPE TO AUSTRALIA IN LESS THAN 3 HOURS",

abstract = "As eluded in previous studies, with special reference to those carried out in the European framework, some innovative high-speed aircraft configurations have now the potential to assure an economically viable high-speed aircraft fleet. They make use of unexploited flight routes in the stratosphere, offering a solution to the presently congested flight paths while ensuring a minimum environmental impact in terms of emitted noise and green-house gases, particularly during stratospheric cruise. However, only a dedicated multi-disciplinary integrated design approach could realize this, by considering airframe architectures embedding the propulsion systems as well as meticulously integrating crucial subsystems. In this context, starting from an in-depth investigation of the current status of the activities, the STRATOFLY project has been funded by the European Commission, under the framework of Horizon 2020 plan, with the aim of assessing the potential of this type of high-speed transport vehicle to reach Technology Readiness Level (TRL) 6 by 2035, with respect to key technological, societal and economical aspects. This paper aims at summarizing the main results achieved so far to solve the main issues related to thermal and structural integrity, low-emissions combined propulsion cycles, subsystems design and integration, including smart energy management, environmental aspects impacting climate change, noise emissions and social acceptance, and economic viability accounting for safety and human factors.",

keywords = "Environmental sustainability, High-speed transportation, Technological challenges",

author = "N. Viola and R. Fusaro and Davide Ferretto and Oscar Gori and Bayindir Saracoglu and Ispir, {Ali Can} and Christophe Schram and Volker Grewe and Plezer, {Johannes Friedrich} and Jan Martinez and Marco Marini and L. Cutrone and G. Saccone and Santiago Hernandez and Karel Lammers and Axel Vincent and Didier Hauglustaine and Bernd Liebhardt and Florian Linke and Daniel Bodmer and Thommie Nilsson and Christer Fureby and Christian Ibron",

year = "2021",

language = "English",

booktitle = "32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021",

publisher = "International Council of the Aeronautical Sciences",

note = "32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021 ; Conference date: 06-09-2021 Through 10-09-2021",

}

Viola, N, Fusaro, R, Ferretto, D, Gori, O, Saracoglu, B, Ispir, AC, Schram, C, Grewe, V, Plezer, JF, Martinez, J, Marini, M, Cutrone, L, Saccone, G, Hernandez, S, Lammers, K, Vincent, A, Hauglustaine, D, Liebhardt, B, Linke, F, Bodmer, D, Nilsson, T , Fureby, C & Ibron, C 2021, H2020 STRATOFLY PROJECT: FROM EUROPE TO AUSTRALIA IN LESS THAN 3 HOURS. in 32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021. International Council of the Aeronautical Sciences, 32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021, Shanghai, China, 2021/09/06.

H2020 STRATOFLY PROJECT: FROM EUROPE TO AUSTRALIA IN LESS THAN 3 HOURS. / Viola, N.; Fusaro, R.; Ferretto, Davide et al.
32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021. International Council of the Aeronautical Sciences, 2021.

Research output: Chapter in Book/Report/Conference proceeding › Paper in conference proceeding › peer-review

TY - GEN

T1 - H2020 STRATOFLY PROJECT

T2 - 32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021

AU - Viola, N.

AU - Fusaro, R.

AU - Ferretto, Davide

AU - Gori, Oscar

AU - Saracoglu, Bayindir

AU - Ispir, Ali Can

AU - Schram, Christophe

AU - Grewe, Volker

AU - Plezer, Johannes Friedrich

AU - Martinez, Jan

AU - Marini, Marco

AU - Cutrone, L.

AU - Saccone, G.

AU - Hernandez, Santiago

AU - Lammers, Karel

AU - Vincent, Axel

AU - Hauglustaine, Didier

AU - Liebhardt, Bernd

AU - Linke, Florian

AU - Bodmer, Daniel

AU - Nilsson, Thommie

AU - Fureby, Christer

AU - Ibron, Christian

PY - 2021

Y1 - 2021

N2 - As eluded in previous studies, with special reference to those carried out in the European framework, some innovative high-speed aircraft configurations have now the potential to assure an economically viable high-speed aircraft fleet. They make use of unexploited flight routes in the stratosphere, offering a solution to the presently congested flight paths while ensuring a minimum environmental impact in terms of emitted noise and green-house gases, particularly during stratospheric cruise. However, only a dedicated multi-disciplinary integrated design approach could realize this, by considering airframe architectures embedding the propulsion systems as well as meticulously integrating crucial subsystems. In this context, starting from an in-depth investigation of the current status of the activities, the STRATOFLY project has been funded by the European Commission, under the framework of Horizon 2020 plan, with the aim of assessing the potential of this type of high-speed transport vehicle to reach Technology Readiness Level (TRL) 6 by 2035, with respect to key technological, societal and economical aspects. This paper aims at summarizing the main results achieved so far to solve the main issues related to thermal and structural integrity, low-emissions combined propulsion cycles, subsystems design and integration, including smart energy management, environmental aspects impacting climate change, noise emissions and social acceptance, and economic viability accounting for safety and human factors.

AB - As eluded in previous studies, with special reference to those carried out in the European framework, some innovative high-speed aircraft configurations have now the potential to assure an economically viable high-speed aircraft fleet. They make use of unexploited flight routes in the stratosphere, offering a solution to the presently congested flight paths while ensuring a minimum environmental impact in terms of emitted noise and green-house gases, particularly during stratospheric cruise. However, only a dedicated multi-disciplinary integrated design approach could realize this, by considering airframe architectures embedding the propulsion systems as well as meticulously integrating crucial subsystems. In this context, starting from an in-depth investigation of the current status of the activities, the STRATOFLY project has been funded by the European Commission, under the framework of Horizon 2020 plan, with the aim of assessing the potential of this type of high-speed transport vehicle to reach Technology Readiness Level (TRL) 6 by 2035, with respect to key technological, societal and economical aspects. This paper aims at summarizing the main results achieved so far to solve the main issues related to thermal and structural integrity, low-emissions combined propulsion cycles, subsystems design and integration, including smart energy management, environmental aspects impacting climate change, noise emissions and social acceptance, and economic viability accounting for safety and human factors.

KW - Environmental sustainability

KW - High-speed transportation

KW - Technological challenges

M3 - Paper in conference proceeding

AN - SCOPUS:85124476540

BT - 32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021

PB - International Council of the Aeronautical Sciences

Y2 - 6 September 2021 through 10 September 2021

ER -

H2020 STRATOFLY PROJECT: FROM EUROPE TO AUSTRALIA IN LESS THAN 3 HOURS

Abstract

Conference

Subject classification (UKÄ)

Free keywords

UN SDGs

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Cite this