Aerodynamic Performance and Wake Flow of Crosswind Kite Power Systems

Kheiri, Mojtaba; Victor, Samson; Rangriz, Sina; Karakouzian, Mher Marc; Bourgault, F.

doi:10.3390/en15072449

Cited by 7 publications

(3 citation statements)

References 44 publications

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“…AWESs Aero S: [3,4] S: [5][6][7], U: [8] S: [9,10], U: [11,12] Structure [3] [6] [5,7,9] FSI [3,5,7] [6] [9,13] Atmosphere [12,14,15] [4] (LES), [12] (RANS) Dynamics [8] [4,16] [ 5,17] In Table 1, we review several levels of fidelity for different fields. In aerodynamics, lowfidelity models are based on the lifting-line techniques or look-up tables.…”

Section: Field Of Study Low Fidelity Mid-fidelity High Fidelitymentioning

confidence: 99%

“…In [4], the dynamic motion of an AWE system was considered with the low-fidelity modeling of AWES aerodynamics using actuator methods and steady airfoil coefficients in a large-eddy simulation (LES) of wind. Kheiri et al [12] analyzes the wake flow of an AWE system using unsteady Reynolds-average Navier-Stokes (RANS) for both AWE system aerodynamics and wind simulation. Efforts were made by Kaufman-Martin et al [14] and Gaunaa et al [15] to develop low-cost models for AWE wake and induction.…”

Section: Field Of Study Low Fidelity Mid-fidelity High Fidelitymentioning

confidence: 99%

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Wing Deformation of an Airborne Wind Energy System in Crosswind Flight Using High-Fidelity Fluid–Structure Interaction

et al. 2023

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Airborne wind energy (AWE) is an emerging technology for the conversion of wind energy into electricity. There are many types of AWE systems, and one of them flies crosswind patterns with a tethered aircraft connected to a generator. The objective is to gain a proper understanding of the unsteady interaction of air and this flexible and dynamic system during operation, which is key to developing viable, large AWE systems. In this work, the effect of wing deformation on an AWE system performing a crosswind flight maneuver was assessed using high-fidelity time-varying fluid–structure interaction simulations. This was performed using a partitioned and explicit approach. A computational structural mechanics (CSM) model of the wing structure was coupled with a computational fluid dynamics (CFD) model of the wing aerodynamics. The Chimera/overset technique combined with an arbitrary Lagrangian–Eulerian (ALE) formulation for mesh deformation has been proven to be a robust approach to simulating the motion and deformation of an airborne wind energy system in CFD simulations. The main finding is that wing deformation in crosswind flights increases the symmetry of the spanwise loading. This property could be used in future designs to increase the efficiency of airborne wind energy systems.

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Section: Field Of Study Low Fidelity Mid-fidelity High Fidelitymentioning

confidence: 99%

Section: Field Of Study Low Fidelity Mid-fidelity High Fidelitymentioning

confidence: 99%

Wing Deformation of an Airborne Wind Energy System in Crosswind Flight Using High-Fidelity Fluid–Structure Interaction

et al. 2023

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“…However, that study focuses on a steady horizontal flight, where the crosswind motion was neglected and the control surfaces were set in at a fixed position. Keihri et al [3] focused on the wake flow of an AWES system using unsteady RANS for both the AWE system aerodynamics and wind simulation assuming circular flight motion. Hence, they considered only the main wing and neglected the control surfaces.…”

Section: Introductionmentioning

confidence: 99%

Moving control surfaces in a geometry-resolved CFD model of an airborne wind energy system

Pynaert,

Haas,

Wauters

et al. 2024

J. Phys.: Conf. Ser.

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Properly understanding the unsteady interaction of the wind with the aircraft is critical to develop reliable airborne wind energy (AWE) systems. High-fidelity simulation tools are needed to accurately predict these interactions, providing insights into the design and operation of efficient and safe AWE systems. In this work, we present a computational fluid dynamics (CFD) framework of an airborne wind system which resolves all lifting surfaces and includes moving control surfaces. This work considers a reference multi-megawatt ground-gen pumping system. To simulate complex fluid flow problems, with large rigid-body motion and deflecting control surfaces using CFD, we opt for the Chimera/overset technique. The goal of this contribution is to demonstrate the effect of the control surfaces in the CFD framework. This work is a major milestone in the ongoing development of high-fidelity aero-servo-elastic simulation models for airborne wind energy systems.

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Interactional Aerodynamics Analysis of a Multirotor Energy Kite

Mehr,

Alvarez,

Ning

2024

Wind Energy

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Airborne wind energy (AWE) technology aspires to provide increased options for wind energy harvesting at a lower cost than conventional turbines. As AWE technology is still in its infancy, there is relatively little published information concerning its aerodynamic details. In this study, we apply the FLOWUnsteady suite of aerodynamic analysis tools—including a vortex particle method for wakes and actuator line methods for rotors and wings—to the analysis of a fixed‐wing, on‐board generation, wind harvesting aircraft (or windcraft for short). Specifically, we explore variations in the rotation directions and vertical and horizontal (front to back) spacing of the rotors to understand the complex interactional aerodynamics of a multirotor windcraft design. Our results indicate that for the configurations presented herein, the rotor‐on‐rotor and wing‐on‐rotor interactions induce maximum total variations on cumulative rotor performance of less than 3% relative to baseline, with most configurations varying from baseline by 2% or less. In addition, rotor‐on‐wing interactions cause decreases in wing lift coefficient of up to roughly 7% (for the configurations simulated) relative to the isolated wing. Furthermore, through selecting specific rotor rotation directions, it is possible to prescribe a portion of the shape of the wing lift distribution. Further exploration, perhaps with the assistance of optimization techniques, may yield greater insights into this uncharted space of windcraft interactional aerodynamics.

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Aerodynamic Performance and Wake Flow of Crosswind Kite Power Systems

Cited by 7 publications

References 44 publications

Wing Deformation of an Airborne Wind Energy System in Crosswind Flight Using High-Fidelity Fluid–Structure Interaction

Wing Deformation of an Airborne Wind Energy System in Crosswind Flight Using High-Fidelity Fluid–Structure Interaction

Moving control surfaces in a geometry-resolved CFD model of an airborne wind energy system

Interactional Aerodynamics Analysis of a Multirotor Energy Kite

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