Numerical Study of the Roughness Influence on NACA 63-430 Profile Aerodynamic Performance

In turbines, secondary vortices and tip leakage vortices develop and interact with each other. In order to understand the flow physics of vortices interaction, the effects of incoming vortex on the downstream tip leakage flow are investigated in terms of the aerodynamic performance in a turbine cascade. Experimental, numerical and analytical methods are used. In the experiment, a swirl generator was used upstream near the casing to generate the incoming vortex, which interacted with the tip leakage vortex in the turbine cascade. The swirl generator was located at ten different pitchwise locations to simulate the quasi-steady effects. In the numerical study, a Rankine-like vortex was defined at the inlet of the computational domain to simulate the incoming swirling vortex. Incoming vortices with opposite directions were investigated. The vorticity of the positive incoming swirling vortex has a large vector in the same direction as that of the tip leakage vortex. In the case of the positive incoming swirling vortex, the vortex mixes with the tip leakage vortex to form one vortex near the tip as it transports downstream. The vortices interaction reduces the vorticity of the flow near the tip, as well as the loss by making up for the streamwise momentum within the tip leakage vortex core. In contrast, the negative incoming swirling vortex has little effects on the tip leakage vortex and the loss. As the negative incoming swirling vortex transports downstream, it is separated from the tip leakage vortex and forms two vortices. A triple-vortices-interaction kinetic analytical model and one-dimensional mixing model are proposed to explain the mechanism of vortex interaction on the aerodynamic performance.

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Numerical study of unsteady flow and exciting force for swept turbomachinery blades

Thermal Science ◽

10.2298/tsci160205199z ◽

2016 ◽

Vol 20 (suppl. 3) ◽

pp. 669-676

Author(s):

Di Zhang ◽

Ma Jiao-Bin ◽

Qi Jing

Keyword(s):

Boundary Layer ◽

Unsteady Flow ◽

Pressure Fluctuation ◽

Numerical Study ◽

Flow Characteristics ◽

Aerodynamic Performance ◽

Rotor Blades ◽

Stable Operation ◽

Straight Blade ◽

Excitation Force

The aerodynamic performance of blade affects the vibration characteristics and stable operation of turbomachinery closely. The aerodynamic performance of turbine stage can be improved by using swept blade. In this paper, the RANS method and the RNG k-? turbulence mode were adopted to investigate the unsteady flow characteristics and excitation force of swept blade stage. According to the results, for the swept blade, the fluid of boundary layer shifts in radial direction due to the influence of geometric construction. It is observed that there is similar wake development for several kinds of stators, and the wake has a notable effect on the boundary layer of the rotor blades. When compared with straight blade, pressure fluctuation of forward-swept blade is decreased while the pressure fluctuation of backward-swept blade is increased. The axial and tangential fundamental frequency excitation force factors of 15?forward-swept blade are 0.139 and 0.052 respectively, which are the least, and all excitation force factors are in the normal range. The excitation factor of the forward-swept blade is decreased compared with straight blade, and the decreasing percentage is closely related to the swept angle. As for backward-swept blades, the situation is the other way around. Additionally, the change of axial excitation factor is more obvious. So the vibration reduction performance of forward-swept blade is better.

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Numerical Analysis of Effect of Leading-Edge Rotating Cylinder on NACA0021 Symmetric Airfoil

European Journal of Engineering Research and Science ◽

10.24018/ejers.2019.4.7.1385 ◽

2019 ◽

Vol 4 (7) ◽

pp. 11-17

Author(s):

Md. Abdus Salam ◽

Vikram Deshpande ◽

Nafiz Ahmed Khan ◽

M. A. Taher Ali

Keyword(s):

Free Stream ◽

Numerical Study ◽

Tangential Velocity ◽

Leading Edge ◽

Rotating Cylinder ◽

Aerodynamic Performance ◽

Stream Velocity ◽

Surface Boundary ◽

Lower Velocity ◽

Numerical Studies

The moving surface boundary control (MSBC) has been a Centre stage study for last 2-3 decades. The preliminary aim of the study was to ascertain whether the concept can improve the airfoil characteristics. Number of experimental and numerical studies pointed out that the MSBC can superiorly enhance the airfoil performance albeit for higher velocity ratios (i.e. cylinder tangential velocity to free stream velocity). Although abundant research has been undertaken in this area on different airfoil performances but no attempt was seen to study effect of MSBC on NACA0021 airfoil for and also effects of lower velocity ratios. Thus, present paper focusses on numerical study of modified NACA 0021 airfoil with leading edge rotating cylinder for velocity ratios (i.e.) between 1 to 1.78 at different angles of attack. The numerical study indicates that the modified airfoil possess better aerodynamic performance than the base airfoil even at lower velocity ratios (i.e. for velocity ratios 0.356 and beyond). The study also focusses on reason for improvement in aerodynamic performance by close look at various parameters.

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A Numerical Study of Aerodynamic Performance and Noise of a Bionic Airfoil Based on Owl Wing

Advances in Mechanical Engineering ◽

10.1155/2014/859308 ◽

2014 ◽

Vol 6 ◽

pp. 859308 ◽

Cited By ~ 3

Author(s):

Xiaomin Liu ◽

Xiang Liu

Keyword(s):

Reynolds Number ◽

Unsteady Flow ◽

Noise Reduction ◽

Numerical Study ◽

Aerodynamic Performance ◽

Centrifugal Fan ◽

Surface Geometry ◽

Airfoil Surface ◽

Acoustic Sources ◽

Bionic Airfoil

Noise reduction and efficiency enhancement are the two important directions in the development of the multiblade centrifugal fan. In this study, we attempt to develop a bionic airfoil based on the owl wing and investigate its aerodynamic performance and noise-reduction mechanism at the relatively low Reynolds number. Firstly, according to the geometric characteristics of the owl wing, a bionic airfoil is constructed as the object of study at Reynolds number of 12,300. Secondly, the large eddy simulation (LES) with the Smagorinsky model is adopted to numerically simulate the unsteady flow fields around the bionic airfoil and the standard NACA0006 airfoil. And then, the acoustic sources are extracted from the unsteady flow field data, and the Ffowcs Williams-Hawkings (FW-H) equation based on Lighthill's acoustic theory is solved to predict the propagation of these acoustic sources. The numerical results show that the lift-to-drag ratio of bionic airfoil is higher than that of the traditional NACA 0006 airfoil because of its deeply concave lower surface geometry. Finally, the sound field of the bionic airfoil is analyzed in detail. The distribution of the A-weighted sound pressure levels, the scaled directivity of the sound, and the distribution of dP/dt on the airfoil surface are provided so that the characteristics of the acoustic sources could be revealed.

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A Numerical Study Into the Influence of Leading Edge Tubercles on the Aerodynamic Performance of a Highly Cambered High Lift Airfoil Wing at Different Reynolds Numbers

10.1115/1.0004227v ◽

2021 ◽

Author(s):

Amr Abdelrahman Khedr ◽

Amr Emam ◽

Ihab Adam ◽

Hamdy Hassan ◽

Shinichi Ookawara ◽

...

Keyword(s):

Numerical Study ◽

Leading Edge ◽

Reynolds Numbers ◽

Aerodynamic Performance ◽

High Lift

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Gurney Flap Implementation on a DU91W250 Airfoil

Proceedings ◽

10.3390/proceedings2231448 ◽

2018 ◽

Vol 2 (23) ◽

pp. 1448 ◽

Cited By ~ 1

Author(s):

Iñigo Aramendia ◽

Aitor Saenz-Aguirre ◽

Unai Fernandez-Gamiz ◽

Ekaitz Zulueta ◽

Jose Manuel Lopez-Guede ◽

...

Keyword(s):

Flow Control ◽

Numerical Study ◽

Lift Coefficient ◽

Optimization Technique ◽

Electrical Power ◽

Aerodynamic Performance ◽

Control Element ◽

Mechanical Fatigue ◽

Gurney Flap ◽

Fatigue Loads

The increasing capability of Wind Turbine (WT) based power generation systems has derived in an increment of the WT rotor diameter, i.e., longer rotor blades. This results in an increase of the electrical power generated but also in instabilities in the operation of the WT, especially due to the mechanical fatigue loads generated in its elements. In this context, flow control has appeared as a solution to improve the aerodynamic performance of the blades. These devices not only increase lift coefficient but also reduce mechanical fatigue loads. This paper presents a detailed numerical analysis of the effects of placing a passive flow control element, a Gurney Flap (GF), in a DU91W250 airfoil. Moreover, a numerical study of the influence of the GF length on the aerodynamic performance of the blade has been carried out. This study is considered as a basis for the development of an optimization technique of the GF length for long WT blades.

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Numerical Analysis of a Rooftop Vertical Axis Wind Turbine

ASME 2011 5th International Conference on Energy Sustainability, Parts A, B, and C ◽

10.1115/es2011-54173 ◽

2011 ◽

Cited By ~ 1

Author(s):

N. Cristobal Uzarraga-Rodriguez ◽

A. Gallegos-Mun˜oz ◽

J. Manuel Riesco A´vila

Keyword(s):

Numerical Analysis ◽

Wind Turbine ◽

Numerical Study ◽

Vertical Axis ◽

Turbine Rotor ◽

Aerodynamic Performance ◽

Power Coefficient ◽

Vertical Axis Wind Turbine ◽

Sliding Mesh ◽

Mesh Model

A numerical analysis of a rooftop vertical axis wind turbine (VAWT) for applications in urban area is presented. The numerical simulations were developed to study the flow field through the turbine rotor to analyze the aerodynamic performance characteristics of the device. Three different blade numbers of wind turbine are studied, 2, 3 and 4, respectively. Each one of the models was built in a 3D computational model. The effects generated in the performance of turbines by the numbers of blades are considered. A Sliding Mesh Model (SMM) capability was used to present the dimensionless form of coefficient power and coefficient moment of the wind turbine as a function of the wind velocity and the rotor rotational speed. The numerical study was developed in CFD using FLUENT®. The results show the aerodynamic performance for each configuration of wind turbine rotor. In the cases of Rooftop rotor the power coefficient increases as the blade number increases, while in the case of Savonius rotor the power coefficient decrease as the blades number increases.

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