Transport Weight Reduction Through MDO: The Strut-Braced Wing Transonic Transport

Gern, Frank H.; Ko, Andy; Llc, Avid; Haftka, R. T.; Kapania, Rakesh K.; Mason, William H.

doi:10.2514/6.2005-4667

Cited by 19 publications

(10 citation statements)

References 19 publications

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“…The analyses are performed by in-house codes which are linked to the ModelCenter interface via C++ or Python plugins known as Wrappers. Details about the various wrappers and their purposes have been explained in detail in previous studies [4][5][6][7][8][9][10] . The aircraft is designed for 17 load cases, which represent various flight conditions as shown in Table 1.…”

Section: Methodsmentioning

confidence: 99%

“…1. Following Pfenninger's ideas, the concept of strut-braced wing (SBW) and TBW configurations for long and medium-range civilian transport aircraft has been investigated using multidisciplinary design optimization (MDO) approach [4][5][6][7][8][9][10] . These studies clearly established the potential benefits of such configurations in reducing take-off gross weight (TOGW) and/or fuel consumption.…”

Section: Introductionmentioning

confidence: 99%

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Multidisciplinary Design Optimization of Subsonic Strut-Braced Wing Aircraft

Gupta

Mallik

Kapania

et al. 2014

52nd Aerospace Sciences Meeting

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In this study, a multidisciplinary design optimization technique has been used to investigate the potential benefits of truss-braced wing configurations in the design of medium-range subsonic military cargo aircraft. Previous studies of truss braced wing aircraft (both strut-braced wings) and truss-braced wing) at Virginia Tech for both Boeing-777 and Boeing-737 type of missions have shown that such advanced configurations provide both structural and aerodynamic benefits. The objective of this study was to explore the potential benefits of truss-braced wings in minimizing fuel consumption when applied to a subsonic Lockheed Martin C-130J like aircraft with a cruise Mach number of 0.60, 1800 NM range and a maximum payload of 40,000 lbs. The results show a 10.7% reduction in fuel weight with just a 5%increase in TOGW of the aircraft, a 27% increase in lift to drag ratio and 25% increase in wingspan for strutbraced wing aircraft. This study highlights the benefits of the truss-braced wing configurations for cargo aircraft and provides a comparison amongst various trussbraced wing configurations. For this class of aircraft, the strut-braced wing proves more attractive than a truss-braced wing (strut plus one jury) configuration.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Multidisciplinary Design Optimization of Subsonic Strut-Braced Wing Aircraft

Gupta

Mallik

Kapania

et al. 2014

52nd Aerospace Sciences Meeting

View full text Add to dashboard Cite

show abstract

“…The TBW concept for a Mach 0.85, long-range transport like the Boeing 777-200ER has been extensively studied at Virginia Polytechnic Institute and State University (Virginia Tech) using multidisciplinary design optimization (MDO) tools [6][7][8][9][10][11]. Here, we will consider medium-range transports similar to the Boeing 737-800 and Airbus A320.…”

mentioning

confidence: 99%

Tradeoffs of Wing Weight and Lift/Drag in Design of Medium-Range Transport Aircraft

Shirley

Schetz

Kapania

et al. 2014

Journal of Aircraft

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Wing design involves many compromises, but none more important than the one between aerodynamics, represented by lift-to-drag ratio, and structural weight. Multidisciplinary design optimization is used to compare the effect of configuration changes on wing weight and lift/drag ratio for 1) cantilever, 2) strut-braced, and 3) truss-braced wing aircraft for a medium-range, transonic, 162 passenger mission. Pseudo-Pareto fronts are generated to illustrate maximum lift/drag ratio compared to minimum wing weight. Lower lift/drag ratio aircraft have a shorter, more highly swept wing, with a change in taper at 75% semispan. Higher lft/drag ratio aircraft have much greater span and maximum chord at 33% semispan. To increase lift/drag ratio, both wing-weight and takeoff gross weight penalties must be paid. However, there are high lift/drag ratio designs with low wing-weight penalty that are clearly displayed by the pseudo-Pareto front. Fuel weight minima were found in the high lift/drag ratio and low wing-weight region of the pseudo-Pareto front for the truss-braced wing with both fuselage-mounted and wing-mounted engine configurations and for the cantilever configuration. An interesting pseudo-Pareto front was observed for the wingmounted engine truss-braced wing configuration, where the pseudo-Pareto front almost became an asymptote to a lift/drag ratio of ∼45. Also, one can look across all the configurations and compare attractive designs from each to search for an overall best aircraft design.

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“…1. Following Pfenninger's footsteps [4], the concept of a strut-braced-wing (SBW) configuration was investigated using multidisciplinary design optimization (MDO) tools [5][6][7]. These studies established the potential benefits of such configurations.…”

mentioning

confidence: 99%

Aerodynamic Considerations in the Design of Truss-Braced-Wing Aircraft

Gur

Schetz

Mason

2011

Journal of Aircraft

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This paper describes a study of the effects of several key aerodynamic considerations on the conceptual design of minimum-fuel/emissions, long-range transport, transonic, truss-braced-wing aircraft configurations. This unconventional configuration has a large benefit over conventional cantilever wing configurations. The truss system enables an increased aspect ratio with lower sweep, thickness ratio, and chords, thus exploiting natural laminar flow. The design problem is solved by a multidisciplinary optimization process, which takes into account both aerodynamic and structural considerations. This paper contains several studies, each of which investigates the dependency of the design space on a specific aerodynamic parameter such as the extent of laminar flow on the wing, cruise Mach number, maximum cruise two-dimensional lift coefficient, supercritical characteristics of the airfoil, winglet influence, and intersection fairing design. In addition, various fuselage drag-reduction technologies are investigated: fuselage relaminarization, surface riblets, tailless arrangements, and Goldschmied propulsion apparatus. All of these studies illustrate the large potential of the truss-braced wing along with additional dragreduction technologies, which may substantially decrease the fuel weight and vehicle emissions.

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Transport Weight Reduction Through MDO: The Strut-Braced Wing Transonic Transport

Cited by 19 publications

References 19 publications

Multidisciplinary Design Optimization of Subsonic Strut-Braced Wing Aircraft

Multidisciplinary Design Optimization of Subsonic Strut-Braced Wing Aircraft

Tradeoffs of Wing Weight and Lift/Drag in Design of Medium-Range Transport Aircraft

Aerodynamic Considerations in the Design of Truss-Braced-Wing Aircraft

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