Fully-coupled simulations of the rotorcraft / ship dynamic interface

Emre Alpman; Lyle N. Long; Derek O. Bridges; Joseph F. Horn

Fully-coupled simulations of the rotorcraft / ship dynamic interface

Emre Alpman, Lyle N. Long, Derek O. Bridges, Joseph F. Horn

Research output: Contribution to journal › Conference article › peer-review

Abstract

A fully- coupled simulation tool has been developed to analyze the rotorcraft/ship dynamic interface problem. An existing computational fluid dynamics code and a flight dynamics simulation model have been coupled for this purpose. The flight dynamics model provided the location and orientation of the helicopter and the main rotor as well as the blade loads while the computational fluid dynamics code provided local air velocities. Computations have been performed for a UH-60A hovering behind an aircraft hangar and approaching an LHA class ship. For the solutions the flowfield is assumed to be inviscid and atmospheric turbulence and boundary layer effects have been neglected. The results show that when the helicopter is operating in ground effect or close to solid structures, the interactions between the airwake and the rotor wake can invalidate the one-way coupled solutions.

Original language	English (US)
Pages (from-to)	1367-1382
Number of pages	16
Journal	Annual Forum Proceedings - AHS International
Volume	2
State	Published - 2007
Event	American Helicopter Society International 63rd Annual Forum - Riding the Wave of New Vertical Flight Technology - Virginia Beach, VA, United States Duration: May 1 2007 → May 3 2007

All Science Journal Classification (ASJC) codes

General Engineering

Cite this

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title = "Fully-coupled simulations of the rotorcraft / ship dynamic interface",

abstract = "A fully- coupled simulation tool has been developed to analyze the rotorcraft/ship dynamic interface problem. An existing computational fluid dynamics code and a flight dynamics simulation model have been coupled for this purpose. The flight dynamics model provided the location and orientation of the helicopter and the main rotor as well as the blade loads while the computational fluid dynamics code provided local air velocities. Computations have been performed for a UH-60A hovering behind an aircraft hangar and approaching an LHA class ship. For the solutions the flowfield is assumed to be inviscid and atmospheric turbulence and boundary layer effects have been neglected. The results show that when the helicopter is operating in ground effect or close to solid structures, the interactions between the airwake and the rotor wake can invalidate the one-way coupled solutions.",

author = "Emre Alpman and Long, {Lyle N.} and Bridges, {Derek O.} and Horn, {Joseph F.}",

year = "2007",

language = "English (US)",

volume = "2",

pages = "1367--1382",

journal = "Annual Forum Proceedings - AHS International",

issn = "1552-2938",

publisher = "American Helicopter Society",

note = "American Helicopter Society International 63rd Annual Forum - Riding the Wave of New Vertical Flight Technology ; Conference date: 01-05-2007 Through 03-05-2007",

}

TY - JOUR

T1 - Fully-coupled simulations of the rotorcraft / ship dynamic interface

AU - Alpman, Emre

AU - Long, Lyle N.

AU - Bridges, Derek O.

AU - Horn, Joseph F.

PY - 2007

Y1 - 2007

N2 - A fully- coupled simulation tool has been developed to analyze the rotorcraft/ship dynamic interface problem. An existing computational fluid dynamics code and a flight dynamics simulation model have been coupled for this purpose. The flight dynamics model provided the location and orientation of the helicopter and the main rotor as well as the blade loads while the computational fluid dynamics code provided local air velocities. Computations have been performed for a UH-60A hovering behind an aircraft hangar and approaching an LHA class ship. For the solutions the flowfield is assumed to be inviscid and atmospheric turbulence and boundary layer effects have been neglected. The results show that when the helicopter is operating in ground effect or close to solid structures, the interactions between the airwake and the rotor wake can invalidate the one-way coupled solutions.

AB - A fully- coupled simulation tool has been developed to analyze the rotorcraft/ship dynamic interface problem. An existing computational fluid dynamics code and a flight dynamics simulation model have been coupled for this purpose. The flight dynamics model provided the location and orientation of the helicopter and the main rotor as well as the blade loads while the computational fluid dynamics code provided local air velocities. Computations have been performed for a UH-60A hovering behind an aircraft hangar and approaching an LHA class ship. For the solutions the flowfield is assumed to be inviscid and atmospheric turbulence and boundary layer effects have been neglected. The results show that when the helicopter is operating in ground effect or close to solid structures, the interactions between the airwake and the rotor wake can invalidate the one-way coupled solutions.

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M3 - Conference article

AN - SCOPUS:34547884331

SN - 1552-2938

VL - 2

SP - 1367

EP - 1382

JO - Annual Forum Proceedings - AHS International

JF - Annual Forum Proceedings - AHS International

T2 - American Helicopter Society International 63rd Annual Forum - Riding the Wave of New Vertical Flight Technology

Y2 - 1 May 2007 through 3 May 2007

ER -

Fully-coupled simulations of the rotorcraft / ship dynamic interface

Abstract

All Science Journal Classification (ASJC) codes

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