Simulation of Helicopter Shipboard Launch and Recovery with Time-Accurate Airwakes

Lee, Dooyong; Sezer-Uzol, Nilay; Horn, Joseph F.; Long, Lyle N.

doi:10.2514/1.6786

Cited by 72 publications

(35 citation statements)

References 20 publications

(19 reference statements)

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“…Characterization and visualization of the "airwake" of a ship underway as been the subject of some research, particularly for the application of helicopter operations; the article by Lee et al contains a survey. 6 These studies often rely on Computational Fluid Dynamics (CFD) in order to predict the flow field around the ship's superstructure; however, one recent research project at the U.S. Naval Academy is correlating CFD results with flow field data gathered in situ on a 33 m training vessel that has been modified to include a scale model flight deck aft of the superstructure.…”

Section: Winds Over the Landing Platformmentioning

confidence: 99%

Shipboard Landing Challenges for Autonomous Parafoils

Hewgley

Yakimenko

Slegers

2011

21st AIAA Aerodynamic Decelerator Systems Technology Conference and Seminar

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This paper examines some of the challenges that must be overcome if future aerial delivery systems are to have the capability to land on the flight deck of a ship underway. The unique aspects of trajectory planning for landing on a ship's flight deck are first examined, followed by formulation of the position estimation problem for a moving target. Some preliminary investigations into characterizing the wind over a moving landing platform at sea are then described. Finally, experimental results are presented for testing of a small prototype autonomous parafoil with a simple moving target on land. Nomenclature ADS

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Section: Winds Over the Landing Platformmentioning

confidence: 99%

Shipboard Landing Challenges for Autonomous Parafoils

Hewgley

Yakimenko

Slegers

2011

21st AIAA Aerodynamic Decelerator Systems Technology Conference and Seminar

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“…The results illustrate that the RANS solver is capable of predicting the fundamental flow characteristics of ship airwake, although there are some deficiencies in detail simulations of turbulent fluctuation. One-way coupling calculations (Forrest, Owen, & Padfield, 2009;Forrest, Owen, Padfield, & Hodge, 2012;Lee, Sezeruzol, Horn, & Long, 2005;Roper, Owen, Padfield, & Hodge, 2006) refer to simulations that only assume the effect of the ship wake on the helicopter, as commonly used in previous analyses of shipboard landing. However, a large discrepancy has been found in the helicopter control inputs compared with the experimental data, due to the rotor-on-ship effect being ignored.…”

Section: Introductionmentioning

confidence: 99%

An investigation of coupling ship/rotor flowfield using steady and unsteady rotor methods

Shi

Zong

et al. 2017

Engineering Applications of Computational Fluid Mechanics

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A coupling numerical methodology has been developed using the Navier-Stokes solver for ship/rotor flowfield simulation during the helicopter shipboard launch. The steady rotor model (SRM) based on the momentum source approach and unsteady rotor model (URM) based on the moving overset mesh method are respectively employed to account for rotor operations. Studies of coupling ship/rotor flowfield on two typical ships highlight complex interactions over the flight deck. It is shown that the rotor-shipboard vortex interaction and recirculation zone are more serious for small-sized-deck destroyers, while on the straight-through-deck ship the helicopter operations are sensitive to asymmetric distribution of lateral velocity caused by the island. Qualitative and quantitative comparisons in terms of vorticity and velocity between SRM and URM solvers have been conducted. The results demonstrate that both methods can capture complex interactions well. The velocity difference is within 1 m/s in most flowfield areas, except the rotor-wake dominant region. With the consideration of computational efficiency, the momentum source approach could be used to effectively conduct the study of helicopter shipboard operations. ARTICLE HISTORY

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“…The current NAVAIR approach is to adopt the advanced Computational Fluid Dynamics (CFD) method to compute the ship airwake offline [1][2][3] and then use the table lookup approach to include the CFD ship airwake solutions into the induced velocity fields, which are used in the blade element model in a real-time Manned Flight Simulator (MFS) [4]. The deficiency of this approach is that only the effects of unsteady ship airwake on the rotor induced flow field are considered but the effects of rotor induced flow on unsteady ship airwake are neglected.…”

Section: Introductionmentioning

confidence: 99%

Reduced-Order Modeling of Rotor-Ship Interaction

Tang

Dinu

Polsky³

2012

50th AIAA Aerospace Sciences Meeting Including the New Horizons Forum and Aerospace Exposition

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To incorporate at least the first-order effects of rotor-ship coupling into the existing realtime flight simulation system, a series of CFD computations have been conducted for the ship alone, the rotor alone, and the two together using an actuator disk to represent the rotor. The first-order effects of rotor-ship coupling are obtained by subtracting the rotor alone and the ship alone solutions from the coupled solutions. To further utilize those CFD solutions in a real-time simulation environment, a reduced-order model of rotor-ship coupling effects has been constructed from the above CFD solution database by using Proper Orthogonal Decomposition and Multi-layer perceptrons Neural Network methods. While the solutions of this reduced-order model are in good agreement with the original CFD solutions, running this reduced-order model on a regular PC only takes several milliseconds, satisfying the requirement of a real-time simulation.

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Simulation of Helicopter Shipboard Launch and Recovery with Time-Accurate Airwakes

Cited by 72 publications

References 20 publications

Shipboard Landing Challenges for Autonomous Parafoils

Shipboard Landing Challenges for Autonomous Parafoils

An investigation of coupling ship/rotor flowfield using steady and unsteady rotor methods

Reduced-Order Modeling of Rotor-Ship Interaction

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