Access the full text.
Sign up today, get DeepDyve free for 14 days.
A. Cresto, N. Viola, R. Fusaro, G. Saccoccia, J. Longo (2016)
Technology Roadmaps Preparation For European Hypersonic And Re-Entry Space Transportation Systems
G. Musgrave, A. Larsen, T. Sgobba (2009)
Safety Design for Space Systems
Maria Viscio, N. Viola, R. Fusaro, V. Basso, M. Marello, M. Pasquinelli, F. Santoro (2014)
On-orbit technology demonstration and validation: methods and tools for mission, system and operations design
Maria Viscio, N. Viola, R. Fusaro, V. Basso (2015)
Methodology for requirements definition of complex space missions and systemsActa Astronautica, 114
R. Fusaro, D. Ferretto, N. Viola (2016)
Model-Based Object-Oriented systems engineering methodology for the conceptual design of a hypersonic transportation system2016 IEEE International Symposium on Systems Engineering (ISSE)
F. Santoro, A. Bianco, Alessandro Bellomo, G. Martucci, N. Viola, R. Fusaro (2015)
Approaches to development of commercial spaceport and associated ground segment driven by specific spaceplane vehicle and mission operation requirements
R. Fusaro, N. Viola, F. Fenoglio, F. Santoro (2017)
Conceptual design of a crewed reusable space transportation system aimed at parabolic flights: stakeholder analysis, mission concept selection, and spacecraft architecture definitionCEAS Space Journal, 9
F. Vita, N. Viola, R. Fusaro, F. Santoro (2015)
Assessment of hypersonic flights operation scenarios: Analysis of launch and reentry trajectories, and derived top level vehicle system and support infrastructure concepts and requirements
N. Viola, R. Fusaro, F. Vita, A. Bianco, F. Fenoglio, Vincenzo Forleo, F. Massobrio, F. Santoro (2015)
Conceptual design and operations of a crewed reusable space transportation system
S. Chiesa, S. Corpino, M. Fioriti, A. Rougier, N. Viola (2013)
Zonal safety analysis in aircraft conceptual design: application to SAvE aircraftProceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, 227
M. Stamatelatos, H. Dezfuli, G. Apostolakis, C. Everline, S. Guarro, D. Mathias, A. Mosleh, T. Paulos, D. Říha, Curtis Smith, W. Vesely, R. Youngblood (2011)
Probabilistic Risk Assessment Procedures Guide for NASA Managers and Practitioners (Second Edition)
PurposeThis paper aims to propose a methodology for a safety and reliability assessment for the conceptual and preliminary design of very complex and disrupting innovative systems like trans-atmospheric vehicles. The proposed methodology differs from existing ones because it does not rely on statistical data at aircraft-level but exploits the statistical population at components-level only. For the sake of clarity, the paper provides some preliminary results of the application of the methodology at system level. The example deals with the safety and reliability assessment of a very complex propulsion system aimed at guaranteeing vertical take-off and landing capabilities of a suborbital vehicle.Design/methodology/approachThe proposed methodology is strongly based on a systems engineering approach. It exploits safety and reliability assessment analyses which have already been developed in both aeronautical and space engineering domains, but it combines them in an innovative way to overcome the lack of statistics at aircraft level. The methodology consists of two different steps: a qualitative top-down process, allowing a functional and physical decomposition of the transportation system and a following quantitative bottom-up approach, which provides the estimation of system-level reliability and safety characteristics starting from the statistical estimation of the components’ characteristics.FindingsThe paper presents a new methodology for the preliminary reliability and safety assessment of innovative transportation systems, such as hypersonic transportation systems. The envisaged methodology will overcome the poorness of statistical data that is usually affecting the conceptual design of breakthrough systems.Research limitations/implicationsThe paper shows the application of the articulated methodology to a limited case study. A complete example of application of the methodology to estimate safety and reliability characteristics at vehicle level will be provided in feature works.Practical implicationsThe methodology has been proposed to be exploited in international research activities in the field of hypersonic transportation systems. Furthermore, a massive application of this approach would allow to create a database for the generation and the update of semi-empirical models focused on high-level estimations of reliability, availability, maintainability and safety (RAMS) characteristics. Moreover, the proposed safety assessment has been conceived to be fully integrated within a typical conceptual design process.Originality/valueThe existing literature about safety and reliability assessment at the early design stages proposes pure statistical approaches which are usually not applicable to highly innovative products, where the statistical population is not existing, for example, in the case of trans-atmospheric vehicles. This paper describes how to overcome this problem, through the exploitation of statistical data at components-level only through the combination of these data to estimate RAMS characteristics at aircraft-level thanks to functional analysis, concept of operations and typical safety assessment tools, like functional hazard analysis, failure mode and effect analysis, reliability block diagram and fault tree analysis.
Aircraft Engineering and Aerospace Technology: An International Journal – Emerald Publishing
Published: May 8, 2018
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.