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Abstract

Aircraft fuselage and struts under the cabin floor play important impact resisting roles in the crashworthiness of an aircraft. This study first investigates the performance of the struts which support floor beams in a typical fuselage section, and compares the energy absorption characteristics of two typical struts—C shape and Wide-flange shape. Then, the vertical drop numerical test of a fuselage section at a velocity of 9 m/s is conducted. The performances of the aircraft fuselage with different struts in cross section and orientation angle are compared. The results show that the specific energy of Wide-flange is higher than that of C shape when subjected to axial impact load. However, in a fuselage section, the struts are subjected to a complex loading condition, resulting in complex impact energy dissipation process in the vertical crash process. The bending rigidity of Wide-flange is greater than that of C shape, as a result that the initial acceleration peak transferred by the strut with Wide-flange shape to the seat is greater than that transferred by C shape strut. The orientation angle of the struts also affects the crashworthiness of the fuselage section.

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Crashworthiness Study on Fuselage Section and Struts under Cabin Floor

Abstract

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References