Comparison of Aero-Propulsive Performance Predictions for Distributed Propulsion Configurations

Borer, Nicholas K.; Derlaga, Joseph M.; Deere, Karen A.; Carter, Melissa B.; Viken, Sally A.; Patterson, Michael D.; Litherland, Brandon L.; Stoll, Alex M.

doi:10.2514/6.2017-0209

Cited by 47 publications

(27 citation statements)

References 32 publications

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“…This performance should be achieved with the increased propulsion system efficiency of the electric motor/battery system. The sizing design study of the wing presented in Reference 1 resulted in a wing design with a wing loading of 45 lb/ft 2 , a wing area of 66.67 ft 2 , an aspect ratio of 15, and a cruise " = 0.75. The higher aspect ratio for the new wing is meant to minimize induced drag at cruise, since the new wing's cruise lift coefficient is much higher than the original P2006T.…”

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confidence: 99%

“…The higher aspect ratio for the new wing is meant to minimize induced drag at cruise, since the new wing's cruise lift coefficient is much higher than the original P2006T. The original P2006T has a wing loading of 16.365 lb/ft 2 , a wing area of 158.88 ft 2 , an aspect ratio of 8.8, and a cruise " = 0.275. The specially designed X-57 airfoil is tailored for a cruise lift coefficient of 0.85 and incorporates a 25% chord flap.…”

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confidence: 99%

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

Deere

Viken

Carter

et al. 2017

35th AIAA Applied Aerodynamics Conference

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A variety of tools, from fundamental to high order, have been used to better understand applications of distributed electric propulsion to aid the wing and propulsion system design of the Leading Edge Asynchronous Propulsion Technology (LEAPTech) project and the X-57 Maxwell airplane. Three highfidelity, Navier-Stokes computational fluid dynamics codes used during the project with results presented here are FUN3D, STAR-CCM+, and OVERFLOW. These codes employ various turbulence models to predict fully turbulent and transitional flow. Results from these codes are compared for two distributed electric propulsion configurations: the wing tested at NASA Armstrong on the Hybrid-Electric Integrated Systems Testbed truck, and the wing designed for the X-57 Maxwell airplane. Results from these computational tools for the high-lift wing tested on the Hybrid-Electric Integrated Systems Testbed truck and the X-57 high-lift wing presented compare reasonably well. The goal of the X-57 wing and distributed electric propulsion system design achieving or exceeding the required " = 3.95 for stall speed was confirmed with all of the computational codes. Nomenclature Symbols # drag coefficient a angle of attack, degrees #,%&'()* drag coefficient, pylons contribution Δ delta #,,-). drag coefficient, wing contribution #,/0 drag coefficient, tip nacelles contribution Acronyms #,10" drag coefficient, high-lift nacelles contribution BSL Menter kbasic turbulence model " lift coefficient CFL pseudo time advancement Courant-Friedrichs-Lewy ",344 effective lift coefficient: " + ",%5(% DEP distributed electric propulsion ",678 maximum lift coefficient HLN high-lift nacelles ",%5(% lift coefficient from the contribution of propeller thrust in lift direction KCAS KEAS knots calibrated airspeed knots equivalent airspeed 6

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confidence: 99%

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confidence: 99%

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

Deere

Viken

Carter

et al. 2017

35th AIAA Applied Aerodynamics Conference

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“…Camber is added to the VLM mesh to obtain the expected lift coefficient at zero angle of attack. This is determined based on 2-D lift coefficient of the NASA GA(W)-2 airfoil at 2 • angle of incidence as predicted by XFOIL, which is 0.74, and the value predicted using CFD in the literature [29], which is roughly 0.8. Based on the 2-D drag coefficient data from XFOIL, we use a constant parasitic wing drag estimate of C Dp = 0.01.…”

Section: Aerodynamic Coefficients and Validationmentioning

confidence: 99%

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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“…The use of multiple rotors operating in close proximity introduces complicated aerodynamic interactions that are not well understood, are not captured through conventional design tools, and need to be addressed in the conceptual design stage. [12][13][14] For instance, Yoon et al 15 investigated the effects of separation distance between rotors on a quad tilt-rotor aircraft in hover, discovering a myriad of beneficial and counterproductive interactions between rotors and airframe. Using an unsteady detached-eddy Reynolds-average Navier-Stokes (RANS) solver, they simulated the rotors operating at a high Reynolds number with and without the aircraft body.…”

Section: Introductionmentioning

confidence: 99%

Modeling Multirotor Aerodynamic Interactions Through the Vortex Particle Method

Alvarez

Ning

2019

AIAA Aviation 2019 Forum

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Distributed electric propulsion and vertical takeoff and landing has recently opened a new design space for urban air mobility. However, the use of multiple rotors operating in close proximity introduces complicated aerodynamic interactions that are not well understood, are not captured through conventional design tools, and need to be addressed in the conceptual design stage. This study investigates the accuracy of the viscous vortex particle method (VPM) in modeling rotor-on-rotor aerodynamic interactions in a sideby-side configuration as encountered in tilt-rotor, quadrotor, and distributed propulsion aircraft. The VPM approach has the potential to enable the use of mid/high fidelity models capturing multirotor interactions during conceptual design. Validation of the individual rotor is presented in both hovering and forward-flight configurations at both low and high Reynolds numbers. Validation of the hovering multirotor is then presented, followed by a detailed parametric study of rotor-to-rotor interactions during hover and forward flight, constructing the response surface of thrust, torque, and propulsive efficiency as a function of operational parameters.

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Comparison of Aero-Propulsive Performance Predictions for Distributed Propulsion Configurations

Cited by 47 publications

References 32 publications

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

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

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

Modeling Multirotor Aerodynamic Interactions Through the Vortex Particle Method

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