Dynamic inflow-based analysis of pitch changes to hovering rotor

There are two parts to solving rotor aerodynamics. First is pertaining to the rotor blades and other to the wake. Dynamic inflow modelling is a computationally cheap framework to estimate the latter. It is essentially an approach to recreate the non-uniform pressure (and by extension, inflow) distri...

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Main Author: Banerjee, Tridib
Other Authors: -
Format: Thesis-Master by Coursework
Language:English
Published: Nanyang Technological University 2020
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Online Access:https://hdl.handle.net/10356/144208
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Institution: Nanyang Technological University
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spelling sg-ntu-dr.10356-1442082023-03-11T17:58:54Z Dynamic inflow-based analysis of pitch changes to hovering rotor Banerjee, Tridib - School of Mechanical and Aerospace Engineering Institute of Helicopter Technology, Technical University of Munich Hajek, Manfred hajek@tum.de Engineering::Aeronautical engineering::Aerodynamics Engineering::Aeronautical engineering::Propellers There are two parts to solving rotor aerodynamics. First is pertaining to the rotor blades and other to the wake. Dynamic inflow modelling is a computationally cheap framework to estimate the latter. It is essentially an approach to recreate the non-uniform pressure (and by extension, inflow) distribution over the rotor surface with sufficient accuracy. The non-uniform pressure and inflow distributions are obtained using simple harmonic functions or separate functional decomposition in radial and azimuthal states. The field of dynamic inflow is very mature and has been in existence for nearly a century with volumes of improvement and alteration has already been published on the topic. There is a resurgence in their use today to model conventional and coaxial rotors powered by electric drives that has potential for rapid change in operational state. Such a sudden change, for e.g. in rotor frequency or blade pitch, can drastically affect the rotor wake and dynamic inflow modelling is a computationally inexpensive approach to quantify this effect. However, despite the final implementation of the model being simple, dynamic inflow theories, especially the versatile ones like the Peters-He model, are deeply rooted in abstract and complex mathematical domains like spherical harmonics, differential calculus of curvilinear space, functional analysis, numerical analysis and algebraic number theory. They even venture into certain aspects of tensor calculus and differential topology. Given the time elapsed since they were first proposed and the complexity of these theories, it has become increasingly difficult to follow the recent publications on the topic given their apparent choice to avoid stating much of the background mathematical formulations. To further compound the problem, one has to track some extensively used references back to 1950s to find rationale for some derivations and ideas involved. In the current work, two popular dynamic inflow theories - Pitt-Peters and Peters-He, are revisited in their entirety to understand and present a complete and coherent mathematical framework with their necessary assumptions and other supplementary theories. Alternate and more intuitive derivations are proposed. Order of convergence and gain function analyses are performed. Analytical solutions are obtained and state-of-the-art experimental measurements along with CFD results available in literature used to assess the ability of Pitt-Peters and Peters-He models in predicting rotor inflow with prescribed dynamic pitch inputs. Master of Science (Aerospace Engineering) 2020-10-21T02:03:57Z 2020-10-21T02:03:57Z 2020 Thesis-Master by Coursework https://hdl.handle.net/10356/144208 en HT-MA 213/2020 application/pdf Nanyang Technological University
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering::Aeronautical engineering::Aerodynamics
Engineering::Aeronautical engineering::Propellers
spellingShingle Engineering::Aeronautical engineering::Aerodynamics
Engineering::Aeronautical engineering::Propellers
Banerjee, Tridib
Dynamic inflow-based analysis of pitch changes to hovering rotor
description There are two parts to solving rotor aerodynamics. First is pertaining to the rotor blades and other to the wake. Dynamic inflow modelling is a computationally cheap framework to estimate the latter. It is essentially an approach to recreate the non-uniform pressure (and by extension, inflow) distribution over the rotor surface with sufficient accuracy. The non-uniform pressure and inflow distributions are obtained using simple harmonic functions or separate functional decomposition in radial and azimuthal states. The field of dynamic inflow is very mature and has been in existence for nearly a century with volumes of improvement and alteration has already been published on the topic. There is a resurgence in their use today to model conventional and coaxial rotors powered by electric drives that has potential for rapid change in operational state. Such a sudden change, for e.g. in rotor frequency or blade pitch, can drastically affect the rotor wake and dynamic inflow modelling is a computationally inexpensive approach to quantify this effect. However, despite the final implementation of the model being simple, dynamic inflow theories, especially the versatile ones like the Peters-He model, are deeply rooted in abstract and complex mathematical domains like spherical harmonics, differential calculus of curvilinear space, functional analysis, numerical analysis and algebraic number theory. They even venture into certain aspects of tensor calculus and differential topology. Given the time elapsed since they were first proposed and the complexity of these theories, it has become increasingly difficult to follow the recent publications on the topic given their apparent choice to avoid stating much of the background mathematical formulations. To further compound the problem, one has to track some extensively used references back to 1950s to find rationale for some derivations and ideas involved. In the current work, two popular dynamic inflow theories - Pitt-Peters and Peters-He, are revisited in their entirety to understand and present a complete and coherent mathematical framework with their necessary assumptions and other supplementary theories. Alternate and more intuitive derivations are proposed. Order of convergence and gain function analyses are performed. Analytical solutions are obtained and state-of-the-art experimental measurements along with CFD results available in literature used to assess the ability of Pitt-Peters and Peters-He models in predicting rotor inflow with prescribed dynamic pitch inputs.
author2 -
author_facet -
Banerjee, Tridib
format Thesis-Master by Coursework
author Banerjee, Tridib
author_sort Banerjee, Tridib
title Dynamic inflow-based analysis of pitch changes to hovering rotor
title_short Dynamic inflow-based analysis of pitch changes to hovering rotor
title_full Dynamic inflow-based analysis of pitch changes to hovering rotor
title_fullStr Dynamic inflow-based analysis of pitch changes to hovering rotor
title_full_unstemmed Dynamic inflow-based analysis of pitch changes to hovering rotor
title_sort dynamic inflow-based analysis of pitch changes to hovering rotor
publisher Nanyang Technological University
publishDate 2020
url https://hdl.handle.net/10356/144208
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