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Prediction of Circulation Control Performance Characteristics for Super STOL and STOL ApplicationsNaqvi, Messam Abbas 22 August 2006 (has links)
The rapid air travel growth during the last three decades, has resulted in runway congestion at major airports. The current airports infrastructure will not be able to support the rapid growth trends expected in the next decade. Changes or upgrades in infrastructure alone would not be able to satisfy the growth requirements, and new airplane concepts such as the NASA proposed Super Short Takeo and Landing and Extremely Short Takeo and Landing (ESTOL) are being vigorously pursued. Aircraft noise pollution during Takeoff and Landing is another serious concern and efforts are aimed to reduce the airframe noise produced by Conventional High Lift Devices during Takeoff and Landing. Circulation control technology has the prospect of being a good alternative to resolve both the aforesaid issues. Circulation control airfoils are not only capable of producing very high values of lift (Cl values in excess of 8.0) at
zero degree angle of attack, but also eliminate the noise generated by the conventional high lift devices and their associated weight penalty as well as their complex operation and storage. This will ensure not only satisfying the small takeoff and landing distances, but minimal acoustic signature in accordance with FAA requirements.
The Circulation Control relies on the tendency of an emanating wall jet to independently control the circulation and lift on an airfoil. Unlike, conventional airfoil where rear stagnation point is located at the sharp trailing edge, circulation control airfoils possess a round trailing edge, therefore the rear stagnation point is free to move. The location of rear stagnation point is controlled by the blown jet momentum. This provides a secondary control in the form of jet momentum with which the lift generated can be controlled rather the only available control of incidence (angle of attack) in case of conventional airfoils. The use of Circulation control despite its promising potential has been limited only to research applications due to the lack of a simple prediction capability.
This research effort was focused on the creation of a rapid prediction capability of Circulation Control Aerodynamic Characteristics which could help designers with rapid performance estimates for design space exploration. A morphological matrix was created with the available set of options which could be chosen to create this
prediction capability starting with purely analytical physics based modeling to high fidelity CFD codes. Based on the available constraints, and desired accuracy metamodels has been created around the two dimensional circulation control performance results computed using Navier Stokes Equations (Computational Fluid Dynamics). DSS2, a two dimensional RANS code written by Professor Lakshmi Sankar was utilized for circulation control airfoil characteristics. The CFD code was first applied
to the NCCR 1510-7607N airfoil to validate the model with available experimental results. It was then applied to compute the results of a fractional factorial design of experiments array. Metamodels were formulated using the neural networks to the results obtained from the Design of Experiments. Additional validation runs were performed to validate the model predictions. Metamodels are not only capable of
rapid performance prediction, but also help generate the relation trends of response matrices with control variables and capture the complex interactions between control variables. Quantitative as well as qualitative assessments of results were performed by computation of aerodynamic forces and moments and flow field visualizations. Wing characteristics in three dimensions were obtained by integration over the whole wing using Prandtl's Wing Theory.
The baseline Super STOL configuration was then analyzed with the application of circulation control technology. The desired values of lift and drag to achieve the target values of Takeoff and Landing performance were compared with the optimal configurations obtained by the model. The same optimal configurations were then subjected to Super STOL cruise conditions to perform a tradeoff analysis between Takeoff and Cruise Performance. Supercritical airfoils modified for circulation control were also thoroughly analyzed for Takeoff and Cruise performance and may constitute a viable option for Super STOL and STOL Designs. The prediction capability produced by this research effort can be integrated with the current conceptual aircraft modeling and simulation framework. The prediction tool is applicable within the selected ranges of each variable, but methodology
and formulation scheme adopted can be applied to any other design space exploration.
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Estudo experimental do estol dinâmico em um aerofólio naca 0018Oliveira, Thiago Fernandes 14 March 2011 (has links)
Dissertação (mestrado)—Universidade de Brasília, Departamento de Engenharia Mecânica, 2011. / Submitted by Shayane Marques Zica (marquacizh@uol.com.br) on 2011-09-13T19:13:31Z
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2011_ThiagoFernandesOliveira.pdf: 4245386 bytes, checksum: 1a6804b340c8e4f82fe6c1591dffe1e9 (MD5) / O objetivo deste trabalho é o estudo experimental de um perfil aerodinâmico NACA 0018 em movimento angular em túnel de água. Os coeficientes de sustentação, arrasto e momento de arfagem foram medidos estaticamente e dinamicamente (durante a movimentação angular do perfil) através de uma célula de carga desenvolvida especificamente para este estudo. O software LabView foi utilizado para a aquisição de dados e controle do experimento. Os ensaios foram realizados para os números de Reynolds iguais a 97.000, 124.000 e 150.000 para os casos estáticos e 124.000 e 150.000 para os casos dinâmicos com velocidades angulares do perfil iguais a 0,06, 0,13 e 0,19 rad/s. Os resultados dos ensaios estáticos foram comparados com a literatura apresentando boa concordância. Os ensaios dinâmicos foram realizados para a verificação do fenômeno de estol dinâmico. Os resultados foram comparados entre os diferentes números de Reynolds. A influência das diferentes velocidades angulares nos casos dinâmicos também foi evidenciada comparando-se inclusive com o caso estático. A visualização do escoamento também foi realizada para complementar a análise. _______________________________________________________________________________ ABSTRACT / The objective of this work is the experimental study of a NACA 0018 airfoil in angular movement in a water tunnel. The lift, drag and pitching moment coefficients were measured statically and dynamically (along the airfoil's angular movement) through a load cell specifically designed for this study. The LabView software was used for the data acquisition and control of the experiment. The tests were performed for Reynolds numbers equal to 97,000, 124,000 and 150,000 for the statics cases and 124,000 and 150,000 for the dynamics cases with angular velocities of the airfoil equal to 0.06, 0.13 e 0.19 rad/s. The results of the statics tests were compared with the literature with good agreement. The dynamic tests were performed to verify the phenomenon of dynamic stall. The results were compared between the different Reynolds numbers. The influence of the angular velocities in the dynamics cases was also evidenced comparing including with the static case. The flow visualization was also performed to complement the analysis.
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Electric Propulsion System for Exceptionally Short Takeoff and Landing Electric Air VehiclesMahvelatishamsabadi, Parisa January 2019 (has links)
Over the past few years, electric propulsion systems have been widely used in automotive applications. The next decade is likely to see the electrification of aerial vehicles. In the past 20 years, the passengers demand in the aviation industry has increased by roughly 5% annually. Drastic increment in the passengers demand leads to many problems such as emission, noise pollution, airports capacity shortage, and high fuel consumption. An electric airplane that can take off and land in an extremely short runway can solve all the mentioned problems. Also, an airplane that is smaller and lighter with the ability to take off and land from an extremely short runway can be used as a new transportation system in congested cities and solve the urban road traffic and compensate for people’s time wasted in traffic. With this in mind, in this thesis, the feasibility of converting a conventional fixed-wing direct-drive propeller airplane to an electric extremely short takeoff and landing airplane has been examined. An overview of the history of electric aerial vehicles and flying cars is conducted where some of these vehicles are still under development phase. The main aim of this thesis is to address the effect of takeoff and landing runway length on the electric motor main specifications, including power, torque, and speed. Also, the effect of cruising speed on the motor specifications are investigated, and it is observed that there is a considerable difference between the amount of required power for the cruising mode and takeoff mode. In the end, the impact of the braking system and airplane weight on the landing distance are examined, and It is found that for an airplane with a cruise-efficient propeller, usage of thrust reverser is not practical and hence it is not recommended. Although if the propeller is designed to have high efficiency at takeoff and landing, the thrust reverser can be a good solution to make the landing runway shorter. / Thesis / Master of Applied Science (MASc)
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Análise experimental das medidas de pressão em regime não-estacionário em um perfil de aerofólio NACA0012 / Experimental analysis of the measures of pressures in unsteady regimen in a profile of airfoil NACA0012Bueno, Ana Paula Franco 29 October 2007 (has links)
As estruturas aeronáuticas estão sujeitas a diversas solicitações, devido principalmente às interações com o escoamento aerodinâmico, que podem causar distúrbios e vibrações, comprometendo seu desempenho. As medidas aerodinâmicas aplicadas em uma aeronave podem ser obtidas por simulações computacionais ou testes experimentais. No entanto, podem existir imperfeições na simulação computacional, como por exemplo, se conseguir reproduzir algumas condições de vôo real. Sendo assim, diversas pesquisas vêm sendo realizadas para solucionar estes problemas. Dentre elas estão os testes experimentais feitos em túnel de vento com modelos de escala real em diversas condições de vôo. Desta forma, a construção de um modelo físico de um aerofólio em escala reduzida e a implementação de sensores a este modelo torna-se uma ferramenta bastante importante para validar resultados teóricos e experimentais. Assim, nesse trabalho realizou-se a construção de um modelo de aerofólio NACA0012, o desenvolvimento de um mecanismo de fixação do modelo ao túnel de vento e a implementação de um controlador de oscilação forçada. O modelo físico realiza oscilações harmônicas, em regime não-estacionário. O objetivo do trabalho foi mapear as medidas de pressão atuantes sobre modelo ensaiado em regime estacionário e não-estacionário e fazer a comparação entre os dois casos. / Aeronautical structures are affected by many loads, most of them given by the aerodynamic flow interactions. These flow interactions may cause vibration leading to structural failure, such as cracks and fatigue. The aerodynamic flow interactions can be measured by experiment or predicted by computational simulation. Otherwise, computational simulations on its own are not reliable and can not reproduce a real flight condition, such as the mean atmospheric turbulence dynamic. Many researches has been done to solve these problems for computational simulations. One of them are the wind tunnel experiments with a full scale models in many flight conditions for posterior comparison. For a smaller wind tunnel, a small scale physical prototype well instrumented becomes an important solution to validate theoretical and experimental results. In the present work the construction of a NACA 0012 airfoil model, the development of a constraint mechanism and the implementation of a forced oscilation control system were done. The physical model oscilates with a given frequency. The aim of present work is to map the pressure measurements actuating on the model, testing it under a steady state condition and a transient condition for posterior comparison of both conditions.
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Análise experimental das medidas de pressão em regime não-estacionário em um perfil de aerofólio NACA0012 / Experimental analysis of the measures of pressures in unsteady regimen in a profile of airfoil NACA0012Ana Paula Franco Bueno 29 October 2007 (has links)
As estruturas aeronáuticas estão sujeitas a diversas solicitações, devido principalmente às interações com o escoamento aerodinâmico, que podem causar distúrbios e vibrações, comprometendo seu desempenho. As medidas aerodinâmicas aplicadas em uma aeronave podem ser obtidas por simulações computacionais ou testes experimentais. No entanto, podem existir imperfeições na simulação computacional, como por exemplo, se conseguir reproduzir algumas condições de vôo real. Sendo assim, diversas pesquisas vêm sendo realizadas para solucionar estes problemas. Dentre elas estão os testes experimentais feitos em túnel de vento com modelos de escala real em diversas condições de vôo. Desta forma, a construção de um modelo físico de um aerofólio em escala reduzida e a implementação de sensores a este modelo torna-se uma ferramenta bastante importante para validar resultados teóricos e experimentais. Assim, nesse trabalho realizou-se a construção de um modelo de aerofólio NACA0012, o desenvolvimento de um mecanismo de fixação do modelo ao túnel de vento e a implementação de um controlador de oscilação forçada. O modelo físico realiza oscilações harmônicas, em regime não-estacionário. O objetivo do trabalho foi mapear as medidas de pressão atuantes sobre modelo ensaiado em regime estacionário e não-estacionário e fazer a comparação entre os dois casos. / Aeronautical structures are affected by many loads, most of them given by the aerodynamic flow interactions. These flow interactions may cause vibration leading to structural failure, such as cracks and fatigue. The aerodynamic flow interactions can be measured by experiment or predicted by computational simulation. Otherwise, computational simulations on its own are not reliable and can not reproduce a real flight condition, such as the mean atmospheric turbulence dynamic. Many researches has been done to solve these problems for computational simulations. One of them are the wind tunnel experiments with a full scale models in many flight conditions for posterior comparison. For a smaller wind tunnel, a small scale physical prototype well instrumented becomes an important solution to validate theoretical and experimental results. In the present work the construction of a NACA 0012 airfoil model, the development of a constraint mechanism and the implementation of a forced oscilation control system were done. The physical model oscilates with a given frequency. The aim of present work is to map the pressure measurements actuating on the model, testing it under a steady state condition and a transient condition for posterior comparison of both conditions.
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