Correction of the definition of mass flow parameter in dynamic inflow modelling

Murakami, Yoh; Houston, S. S.

doi:10.1243/09544100jaero604

Cited by 6 publications

References 8 publications

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On the modelling of gyroplane flight dynamics

Houston

Thomson

2017

Progress in Aerospace Sciences

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The study of the gyroplane, with a few exceptions, is largely neglected in the literature which is indicative of a niche configuration limited to the sport and recreational market where resources are limited. However the contemporary needs of an informed population of owners and constructors, as well as the possibility of a wider application of such low-cost rotorcraft in other roles, suggests that an examination of the mathematical modelling requirements for the study of gyroplane flight mechanics is timely. Rotorcraft mathematical modelling has become stratified in three levels, each one defining the inclusion of various layers of complexity added to embrace specific modelling features as well as an attempt to improve fidelity. This paper examines the modelling of gyroplane flight mechanics in the context of this complexity, and shows that relatively simple formulations are adequate for capturing most aspects of gyroplane trim, stability and control characteristics. In particular the conventional 6 degree-of-freedom model structure is suitable for the synthesis of models from flight test data as well as being the framework for reducing the order of the higher levels of modelling. However, a high level of modelling can be required to mimic some aspects of behaviour observed in data gathered from flight experiments and even then can fail to capture other details. These limitations are addressed in the paper. It is concluded that the mathematical modelling of gyroplanes for the simulation and analysis of trim, stability and control presents no special difficulty and the conventional techniques, methods and formulations familiar to the rotarywing community are directly applicable.

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On the modelling of gyroplane flight dynamics

Houston

Thomson

2017

Progress in Aerospace Sciences

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A general numerical model for rotor aerodynamics based on added mass force

Gao

Chen

et al. 2020

Journal of Renewable and Sustainable Energy

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When wind turbines operate in complex atmospheric environments, the flow fields around their blades are complex and unsteady. To capture the lag characteristics of induced velocity when the dynamic environment of a rotor changes, this study further modified the equilibrium wake model using the blade element momentum and acceleration potential theories. In addition, a novel expression for the added mass force mA=128/75ρR3 was derived. Consequently, a numerical aerodynamics model of a rotor with an added mass force was developed. The model was used to calculate the aerodynamic load of a 5 MW wind turbine under steady wind, turbulence, gust, wind direction change, and rapid pitching. The results demonstrated that the numerical model with added mass force could reflect the rotor aerodynamic performance more accurately than its counterpart. The fluctuation amplitudes of the flapwise and edgewise bending moments of the blade root were smaller than those from the equilibrium wake model. The overshoot in loading, which was caused by the added mass force during pitching, could not be ignored. The research results were compared with experimental data from the National Renewable Energy Laboratory. It was found that the proposed model provided a new strategy for calculating the added mass force and predicted rotor aerodynamic loads more accurately than the model without added mass force.

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Unsteady dynamic load and output performance of the rotor using the dynamic wake theory

Gao

Chen

et al. 2020

Energy Sources, Part A: Recovery, Utilization, and Environmenta

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Correction of the definition of mass flow parameter in dynamic inflow modelling

Cited by 6 publications

References 8 publications

On the modelling of gyroplane flight dynamics

On the modelling of gyroplane flight dynamics

A general numerical model for rotor aerodynamics based on added mass force

Unsteady dynamic load and output performance of the rotor using the dynamic wake theory

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