Litcius/Paper detail

Impact at aircraft level of elastic efficiency of a forward-swept tailplane

Salvatore Corcione, Vincenzo Cusati, Vittorio Memmolo, Fabrizio Nicolosi, Raul Llamas Sandin

2023Aerospace Science and Technology10 citationsDOIOpen Access PDF

Abstract

This paper evaluates the impact at aircraft level of the elastic efficiency of an advanced rear-end concept for a large passenger aircraft, exploiting a low-fidelity yet reliable aeroelastic approach. The innovative concept leverages a forward-swept horizontal tailplane to unlock a tail-fuselage connection such that a structural opening in the aircraft's rear-end is avoided. This installation allows for weight reduction in the structure, resulting in a positive impact on aircraft fuel burn. Moreover, a forward-swept tail has a different aerostructural behaviour that can be exploited to reduce its size with further weight and aerodynamic drag savings. In this respect, elastic efficiency is a crucial parameter for measuring the impact of this configuration at the aircraft design level. It takes into account both aerodynamic and structural characteristics, making it a comprehensive measure of effectiveness. Two different tail arrangements are being considered for an A320 neo-like aircraft: an innovative forward-swept design and a conventional layout that is equivalent. The results indicate that the forward-swept horizontal stabilizer has a higher elastic efficiency compared to the conventional tail arrangement. This could potentially lead to a reduction of the tailplane surface by approximately 2%, while still maintaining the same stability and control characteristics. This reduction in tail size unlocks the potential for fuel savings of approximately 0.5% on a mission profile of 3,400 nautical miles. Elastic efficiency is just one of the advantageous features of this innovative concept. By incorporating all the innovations proposed by the advanced rear-end concept, a weight reduction of up to 20% at the component level is expected. This could potentially result in fuel savings of approximately 2% for an aircraft similar to the A320neo, which has a mission range of 3,400 nautical miles.

Topics & Concepts

FuselageAerodynamicsReduction (mathematics)Aerospace engineeringFlight control surfacesDragSwept wingAeroelasticityFuel efficiencyWingLift-induced dragEngineeringComputer scienceStructural engineeringAutomotive engineeringAerodynamic dragGeometryMathematicsAdvanced Aircraft Design and TechnologiesAerospace and Aviation TechnologyRocket and propulsion systems research