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A Structural Design Concept for a Multi-Shell Blended Wing Body with Laminar Flow Control

GND
115361426X
Affiliation/Institute
Aeronautics Research Center Niedersachsen (NFL), TU Braunschweig
Bishara, Majeed;
GND
(DE-601)778740358
Affiliation/Institute
Institute of Aircraft Design and Lightweight Structures, TU Braunschweig
Horst, Peter;
Affiliation/Institute
Institute of Structural Analysis, Leibniz University of Hannover
Madhusoodanan, Hinesh;
Affiliation/Institute
Institute of Structural Analysis, Leibniz University of Hannover
Brod, Martin;
ORCID
0000-0002-5320-9698
Affiliation/Institute
Institute of Structural Analysis, Leibniz University of Hannover
Daum, Benedikt;
ORCID
0000-0001-7714-3382
Affiliation/Institute
Institute of Structural Analysis, Leibniz University of Hannover
Rolfes, Raimund

Static and fatigue analyses are presented for a new blended wing body (BWB) fuselage concept considering laminar flow control (LFC) by boundary layer suction in order to reduce the aerodynamic drag. BWB aircraft design concepts profit from a structurally beneficial distribution of lift and weight and allow a better utilization of interior space over conventional layouts. A structurally efficient design concept for the pressurized BWB cabin is a vaulted layout that is, however, aerodynamically disadvantageous. A suitable remedy is a multi-shell design concept with a separate outer skin. The synergetic combination of such a multi-shell BWB fuselage with a LFC via perforation of the outer skin to attain a drag reduction appears promising. In this work, two relevant structural design aspects are considered. First, a numerical model for a ribbed double-shell design of a fuselage segment is analyzed. Second, fatigue aspects of the perforation in the outer skin are investigated. A design making use of controlled fiber orientation is proposed for the perforated skin. The fatigue behavior is compared to perforation methods with conventional fiber topologies and to configurations without perforations.

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