Comparison of High-Fidelity Computational Tools for Wing Design of a Distributed Electric Propulsion Aircraft

Deere, Karen A.; Viken, Sally A.; Carter, Melissa; Viken, Jeffrey K.; Derlaga, Joseph M.; Stoll, Alex M.

doi:10.2514/6.2017-3925

Cited by 31 publications

(14 citation statements)

References 15 publications

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“…As stated previously, the camber is adjusted to match the lift coefficient at zero angle of attack. For the cruise configuration with no high-lift nacelles, we find that the lift curve slope matches well and the drag polar falls in between the predictions with fully turbulent and transition models [30]. For the high-lift configuration, we include the propeller force components, and we find that the lift curve slope is under-predicted at low angles of attack.…”

Section: Aerodynamic Coefficients and Validationmentioning

confidence: 57%

“…We validate the aerodynamics model (minus the C D0 term) against RANS CFD predictions [29,30] using OVER-FLOW, STAR-CCM+, and FUN3D in Fig. 4.…”

Section: Aerodynamic Coefficients and Validationmentioning

confidence: 99%

“…The propeller-wing aerodynamics model shows good agreement with CFD data except for the drag at high angles of attack. The cruise data is from Borer et al[29] and the high-lift data is from Deere et al[30].…”

mentioning

confidence: 99%

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Large-scale multidisciplinary optimization of an electric aircraft for on-demand mobility

Hwang

Ning

2018

2018 AIAA/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference

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Distributed electric propulsion is a key enabling technology for on-demand electric aircraft concepts. NASA's X-57 Maxwell X-plane is a demonstrator for this technology, and it features a row of high-lift propellers distributed along the leading edge of its wing to enable better aerodynamic efficiency at cruise and improved ride quality in addition to less noise and emissions. This study applies adjointbased multidisciplinary design optimization to this highly coupled design problem. The propulsion, aerodynamics, and structures are modeled using blade element momentum theory, the vortex lattice method, and finite element analysis, respectively, and the full mission profile is discretized and analyzed. The design variables in the optimization problem include the altitude profile, the velocity profile, battery weight, propeller diameters, propeller rotational speeds, blade profile parameters, wing thickness distribution, and angle of attack. Optimizations take on the order of 10 hours, and a 12% increase in range is observed.

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Section: Aerodynamic Coefficients and Validationmentioning

confidence: 57%

“…We validate the aerodynamics model (minus the C D0 term) against RANS CFD predictions [29,30] using OVER-FLOW, STAR-CCM+, and FUN3D in Fig. 4.…”

Section: Aerodynamic Coefficients and Validationmentioning

confidence: 99%

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Large-scale multidisciplinary optimization of an electric aircraft for on-demand mobility

Hwang

Ning

2018

2018 AIAA/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference

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“…With respect to propulsion, open rotor engines [3] or boundary-layer ingestion [10] is promising options that significantly increase fuel efficiency. Electric propulsion [6], which may be distributed [5], is also attractive options. Biofuels are certain to be an important contributor to the sustainability of any propulsion system that continues to use hydrocarbons [11].…”

Section: Introductionmentioning

confidence: 99%

Modeling hybrid polymer–nanometal lightweight structures

Bhaga

Steeves

2019

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Increasing the environmental sustainability of aviation is a key design goal for commercial aircraft for the foreseeable future. From the perspective of structural engineering, this is accomplished through reducing the mass of aircraft components and structures. Advanced manufacturing techniques offer new avenues for design, enabling more complex structures which can have highly tailored properties. One advanced manufacturing concept is the use of 3D printed polymer preforms that are coated with nanocrystalline metal through electrodeposition. This enables the use of high-performance materials in virtually any geometry. To exploit this manufacturing approach, it is incumbent to have well-established mechanical models of the behavior of such hybrid structures. In particular, hybrid polymer-nanometal structures tend to fail due to compressive instabilities. This paper describes a model of local shell buckling, a typical compressive instability, as it applies to hybrid polymer-nanometal structures. The analysis depends upon the Southwell stress function model for radially loaded solids of rotation, and couples this with the Timoshenko analysis of local shell buckling. This combination is applicable to a range of practical configurations for truss-like hybrid structures.

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“…Consisting of an array of propellers installed upstream of the wing leading edge, a HLPS accelerates the flow observed by the wing, thereby increasing the wing's effective lift coefficient. In the case of the X-57, lift coefficients of 4.5 or greater are possible during takeoff, approach, and landing with moderate blowing of a flapped wing [11][12][13]. The propeller blades (of the HLPS) then conformally fold away against their nacelles during cruise to reduce drag [14].…”

Section: Introductionmentioning

confidence: 99%

Exploring the Effects of Installation Geometry in High-Lift Propeller Systems

Fei

Patterson

German

2018

2018 AIAA Aerospace Sciences Meeting

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A high-lift propeller system is a distributed electric propulsion technology which dedicates an array of wing-mounted tractor propellers to actively augment wing lift during takeoff and landing. This paper describes the results of a wind tunnel experiment dedicated to investigating the effects of high-lift propeller installation geometry on lift generation. Variables investigated include propeller height, offset, and inclination. Results show that propeller height is the most critical variable and that the height for maximum lift depends highly on the angle of attack and flap deflection. In addition, a relationship between optimal propeller height and the wing's unblown lift coefficient is discovered.

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Comparison of High-Fidelity Computational Tools for Wing Design of a Distributed Electric Propulsion Aircraft

Cited by 31 publications

References 15 publications

Large-scale multidisciplinary optimization of an electric aircraft for on-demand mobility

Large-scale multidisciplinary optimization of an electric aircraft for on-demand mobility

Modeling hybrid polymer–nanometal lightweight structures

Exploring the Effects of Installation Geometry in High-Lift Propeller Systems

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