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Zenodo
2026
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| Online Access: | https://doi.org/10.3390/engproc2026133126 |
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| _version_ | 1866901956632510464 |
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| author | Sy, Ousmane Sapre, Shantanu Benard, Emmanuel Morlier, Joseph Le Lamer, Yoann |
| author_facet | Sy, Ousmane Sapre, Shantanu Benard, Emmanuel Morlier, Joseph Le Lamer, Yoann |
| contents | <h1><span>Abstract</span></h1> <p class="MsoNormal">As the aviation industry explores sustainable solutions for next-generation aircraft, the strut-braced wing (SBW) concept has emerged as a promising configuration, combining the enhanced aerodynamic efficiency of high-aspect-ratio (HAR) wings with a significant reduction in wing structural weight compared to conventional cantilever designs. Given the inherent aerodynamics and structural complexities of SBW concepts, developing innovative design methodologies is essential for fully investigating their potential. This work presents a low-fidelity, two-fold design methodology combining an overall aircraft design framework with finite element structural analysis. The approach enables overall aircraft design (OAD) sizing, exploration, and optimization of regional strut-braced wing configurations and assessing the effects of strut connections and jury on the wing’s static and buckling behavior. Trade-off and optimization studies based on the reference ATR-72 aircraft led to an optimal SBW configuration with an aspect ratio of 17.64 and a strut position ratio of 0.543, achieving reductions of about 24% in wing weight and 6.78% in fuel burn. The structural analysis of the optimized SBW indicates that a clamped–clamped strut connection provides superior buckling performance, and incorporating a jury strut effectively mitigates buckling issues while achieving approximately 20% wing weight reduction compared to the configuration without a jury.</p> |
| format | Recurso digital |
| id | zenodo_https___doi_org_10_3390_engproc2026133126 |
| institution | Zenodo |
| language | |
| publishDate | 2026 |
| publisher | Zenodo |
| record_format | zenodo |
| spellingShingle | Exploration of Strut-Braced High-Aspect-Ratio Wings: A Low-Fidelity Framework for Early Aircraft Design Sy, Ousmane Sapre, Shantanu Benard, Emmanuel Morlier, Joseph Le Lamer, Yoann <h1><span>Abstract</span></h1> <p class="MsoNormal">As the aviation industry explores sustainable solutions for next-generation aircraft, the strut-braced wing (SBW) concept has emerged as a promising configuration, combining the enhanced aerodynamic efficiency of high-aspect-ratio (HAR) wings with a significant reduction in wing structural weight compared to conventional cantilever designs. Given the inherent aerodynamics and structural complexities of SBW concepts, developing innovative design methodologies is essential for fully investigating their potential. This work presents a low-fidelity, two-fold design methodology combining an overall aircraft design framework with finite element structural analysis. The approach enables overall aircraft design (OAD) sizing, exploration, and optimization of regional strut-braced wing configurations and assessing the effects of strut connections and jury on the wing’s static and buckling behavior. Trade-off and optimization studies based on the reference ATR-72 aircraft led to an optimal SBW configuration with an aspect ratio of 17.64 and a strut position ratio of 0.543, achieving reductions of about 24% in wing weight and 6.78% in fuel burn. The structural analysis of the optimized SBW indicates that a clamped–clamped strut connection provides superior buckling performance, and incorporating a jury strut effectively mitigates buckling issues while achieving approximately 20% wing weight reduction compared to the configuration without a jury.</p> |
| title | Exploration of Strut-Braced High-Aspect-Ratio Wings: A Low-Fidelity Framework for Early Aircraft Design |
| url | https://doi.org/10.3390/engproc2026133126 |