Please use this identifier to cite or link to this item: https://doi.org/10.48441/4427.1588
Title: The aircraft mass growth and reduction factor
Language: English
Authors: Scholz, Dieter  
Keywords: Luftfahrt; Luftfahrzeug; Flugmechanik; Passagierflugzeug; Flugzeug; Masse; Nutzlast; Reichweite; Betriebskosten; Betriebsleermasse; Flugzeugentwurf; Massenzunahme; aeronautics; airplanes; design; airplanes--performance; payloads; airplanes--fuel consumption; aerodynamics; aircraft; mass; operating empty mass; design; mass growth; range; SFC; DOC
Issue Date: 22-May-2024
Is supplemented by: 10.5281/zenodo.4159259
https://nbn-resolving.org/urn:nbn:de:gbv:18302-aero2020-03-31.011
Conference: Annual Conference of the Society of Allied Weight Engineers 2024 
Abstract: 
Purpose – This project work shows a literature survey, clearly defines the mass growth factor, shows a mass growth iteration, and derives an equation for a direct calculation of the factor (without iteration). Definite values of the factor seem to be missing in literature. To change this, mass growth factors are being calculated for as many of the prominent passenger aircraft as to cover 90% of the passenger aircraft flying today. The dependence of the mass growth factor on requirements and technology is examined and the relation to Direct Operating Costs (DOC) is pointed out. --- Methodology – Calculations start from first principles. Publically available data is used to calculate a list of mass growth factors for many passenger aircraft. Using equations and the resulting relationships, new knowledge and dependencies are gained. --- Findings – The mass growth factor is larger for aircraft with larger operating empty mass ratio, smaller payload ratio, larger specific fuel consumption (SFC), and smaller glide ratio. The mass growth factor increases much with increasing range. The factor depends on an increase in the fixed mass, so this is the same for the payload and empty mass. The mass growth factor for subsonic passenger aircraft is on average 4.2, for narrow body aircraft 3.9 and for wide body aircraft (that tend to fly longer distance) 4.9. In contrast supersonic passenger aircraft show a factor of about 14. --- Practical implications – The mass growth factor has been revisited in order to fully embrace the concept of mass growth and may lead to a better general understanding of aircraft design. --- Social implications – A detailed discussion of aircraft costs as well as aircraft development requires detailed knowledge of the aircraft. By understanding the mass growth factor, consumers can have this discussion with industry at eye level. --- Originality/value – The derivation of the equation for the direct calculation of the mass growth factor and the determination of the factor using the method for 90% of current passenger aircraft was not shown.
URI: http://hdl.handle.net/20.500.12738/15832
DOI: 10.48441/4427.1588
Review status: Currently there is no review planned for this version
Institute: Forschungsgruppe Flugzeugentwurf und -systeme (AERO) 
Department Fahrzeugtechnik und Flugzeugbau 
Fakultät Technik und Informatik 
Type: Presentation
Additional note: SCHOLZ, Dieter, 2024. The Aircraft Mass Growth and Reduction Factor. In: Society of Allied Weight Engineers (SAWE), 83rd International Conference on Mass Properties Engineering. Online, 20-22 May 2024. Available from: https://doi.org/10.48441/4427.1588
Other contributor: Cheema, John Singh 
Appears in Collections:Publications with full text

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