Litcius/Paper detail

Multi-level and multi-objective structural optimization for hypersonic vehicle design

Miguel Rodríguez-Segade, Santiago Hernández, J. Díaz

2024Aerospace Science and Technology15 citationsDOIOpen Access PDF

Abstract

This research introduces a novel methodology for optimizing the structural design of a full-scale hypersonic aircraft, integrating a multifaceted approach across different levels of modelling detail to enhance a variety of performance metrics. The proposed approach is capable of reduce the vehicle mass, while meeting the necessary operational requirements and maintaining an acceptable computational cost. The methodology, based on a coupled bi-level size optimization and denoted as single-objective bi-level optimization (SOBLO), is applied to the passenger cabin of the STRATOFLY MR3 hypersonic cruiser vehicle. This results in a substantial reduction in the baseline concept design weight, estimated to be more than half on average. The procedure is extended to incorporate a multi-objective optimization approach (MOBLO), which generates a Pareto frontier that provides significant information for selecting the optimal trade-off design, considering manufacturability constraints. The outcomes underscore the efficacy of the proposed methodology and highlight its usefulness in sizing complex aircraft configurations, particularly under the demanding loads imposed by a hypersonic flight regime. This approach has the potential to improve the overall production process and enable designers to attain feasible structural design solutions during early stages of development.

Topics & Concepts

SizingHypersonic speedDesign for manufacturabilityMulti-objective optimizationPareto principleEngineeringComputer scienceProcess (computing)Design processEngineering design processSystems engineeringReliability engineeringAutomotive engineeringAerospace engineeringMechanical engineeringWork in processArtVisual artsMachine learningOperating systemOperations managementAdvanced Aircraft Design and TechnologiesProbabilistic and Robust Engineering DesignRocket and propulsion systems research