Boundary element method of incompressible flow past deforming geometries

Vlachos, Nickolas Dimitris

January 1999

No description available.

629.1323

Assessing the Influence of Wake Dynamics on the Performance and Aeroelastic Behavior of Wind Turbines

Kecskemety, Krista Marie

30 August 2012

No description available.

Aerospace Engineering

Wind Turbine

Vortex Wake

Aeroelasticity

An Analysis of Harmonic Airloads Acting on Helicopter Rotor Blades

Riyad, Iftekhar A

06 August 2018

Rotary wing aircrafts in any flight conditions suffer from excessive vibration which makes the passengers feel uncomfortable and causes fatigue failure in the structure. The main sources of vibration are the rotor harmonic airloads which originate primarily from the rapid variation of flow around the blade due to the vortex wake. In this thesis, a mathematical model is developed for rotor blades to compute the harmonic airloads at rotor blades for two flight conditions vertical takeoff and landing, and forward flight. The sectional lift, drag, and pitching moment are computed at a radial blade station for both flight conditions. The lift at a particular radial station is computed considering trailing and shed vortices and summing over each blade. The results for airloads are obtained after considering zeroth, first, and second harmonics. The calculated results for airloads are compared to the experimental flight-test data.

Aerodynamics and Fluid Mechanics

Interfacing comprehensive rotorcraft analysis with advanced aeromechanics and vortex wake models

Liu, Haiying

12 December 2007

This dissertation describes three aspects of the comprehensive rotorcraft analysis. First, a physics-based methodology for the modeling of hydraulic devices within multibody-based comprehensive models of rotorcraft systems is developed. This newly proposed approach can predict the fully nonlinear behavior of hydraulic devices, and pressure levels in the hydraulic chambers are coupled with the dynamic response of the system. The proposed model evaluates relevant hydraulic quantities such as chamber pressures, orifice flow rates, and pressure relief valve displacements. This model could be used to design lead-lag dampers with desirable force and damping characteristics. The second part of this research is in the area of computational aeroelasticity, in which an interface between computational fluid dynamics (CFD) and computational structural dynamics (CSD) is established. This interface enables data exchange between CFD and CSD with the goal of achieving accurate airloads predictions. In this work, a loose coupling approach based on the delta-airload method is developed in a finite-element method based multibody dynamics formulation, DYMORE. A loose coupling analysis between a CFD code, OVERFLOW-2, and a CSD program, DYMORE, is performed to validate this aerodynamic interface. The ability to accurately capture the wake structure around a helicopter rotor is crucial for rotorcraft performance analysis. In the third part of this thesis, a new representation of the wake vortex structure based on Non-Uniform Rational B-Spline (NURBS) curves and surfaces is proposed to develop an efficient model for prescribed and free wakes. The proposed formulation has the potential to reduce the computational cost associated with the use of the Helmholtz¡¯s law and the Biot-Savart law when calculating the induced flow field around the rotor. An efficient free wake analysis will considerably decrease the computational cost of comprehensive rotorcraft analysis, making the approach more attractive to routine use in industrial settings.

NURBS curves/surfaces

Hydraulic modeling

Aerodynamics

DYMORE

Computational aeroelasticity

Vortex wake modeling

Helicopters

Hydraulic models

Aeroelasticity

Aerodynamics

Aerodynamic load

The Aerodynamics and Near Wake of an Offshore Floating Horizontal Axis Wind Turbine

Sebastian, Thomas

01 February 2012

Offshore floating wind turbines represent the future of wind energy. However, significant challenges must be overcome before these systems can be widely used. Because of the dynamics of offshore floating wind turbines -- surge, sway, heave, roll, pitch, and yaw -- and the resulting interactions between the rotor and generated wake, the aerodynamic analysis methods and design codes that have found wide use throughout the wind energy industry may be inadequate. Application of these techniques to offshore floating wind turbine aerodynamics may result in off-optimal designs, effectively handicapping these next-generation systems, thereby minimizing their full potential. This dissertation will demonstrate that the aerodynamics of offshore floating wind turbines are sufficiently different from conventional offshore and onshore wind turbines, warranting the use of higher fidelity analysis approaches. It will outline the development and validation of a free vortex wake code, the Wake Induced Dynamics Simulator, or WInDS, which uses a more physically realistic Lagrangian approach to modeling complex rotor-wake interactions. Finally, results from WInDS simulations of various offshore floating wind turbines under different load conditions will be presented. The simulation results indicate that offshore floating wind turbine aerodynamics are more complex than conventional offshore or onshore wind turbines and require higher fidelity analysis approaches to model adequately. Additionally, platform pitching modes appear to drive the most aerodynamically-significant motions, followed by yawing modes. Momentum balance approaches are shown to be unable to accurately model these dynamic systems, and the associated dynamic inflow methods respond to velocity changes at the rotor incorrectly. Future offshore floating wind turbine designs should strive to either minimize platform motions or be complementarily optimized, via higher fidelity aerodynamic analysis techniques, to account for them. It is believed that this dissertation is the first in-depth study of offshore floating wind turbine aerodynamics and the applicability of various analysis methods.

free vortex wake

lifting line

matlab

offshore floating wind turbine

vortex filament

wind energy

Industrial Engineering

Mechanical Engineering

Design and Experimentation of Darrieus Vertical Axis Wind Turbines

Gonzalez Campos, Jose Alberto

07 September 2020

No description available.

Energy

Mechanical Engineering

Fluid Dynamics

Engineering

Aerospace Engineering

Vertical Axis Wind Turbines - VAWT

Straight-Bladed

Helical-Bladed

Troposkien-Bladed

Darrieus Wind Turbines

MPPT Control

Wind Tunnel Experimentation

Blade Element Theory - BEM

Double Multiple Streamtube Model - DMST

Free-Vortex Wake Model - LLFVW