Effect of airfoil distance to water surface on static stall

Authors

  • Y. Azargoon Department of Mechanical Engineering, Ferdowsi University of Mashhad, Iran. Phone: +989151095791.
  • M. H. Djavareshkian Department of Mechanical Engineering, Ferdowsi University of Mashhad, Iran. Phone: +989151095791.
  • E. Esmaeilifar Department of Mechanical Engineering, Ferdowsi University of Mashhad, Iran. Phone: +989151095791.

DOI:

https://doi.org/10.15282/jmes.14.1.2020.27.0512

Keywords:

Water Surface, Separation, Static stall, airfoil

Abstract

In this study, viscous, turbulent, and steady flow around an airfoil near the water surface has been simulated through a numerical method. In this simulation, Navier-Stokes equations have been solved using the finite volume method with a discretized second-order accuracy and PIMPLE algorithm. The Volume of Fraction (VOF) method has been employed to predict the free surface flow. A part of the simulation results has been validated through numerical and experimental data. Besides considering the style of flow separation in the angles of numerous attacks and airfoil static stall near the surface of the water. For this purpose, the airfoil simulation has been processed airfoil in the 68,000 Reynolds number, angle of attack of 2.5 to 11 degree and different distances from the water surface ( h/c = 0.5, 1,  ). In a larger angle of attacks, flow is initially separated from the leading edge of the surface, and then it attaches to the surface at a lower point. This reattachment leads to an increase in adverse pressure gradient and the formation of a larger separation in the downstream of the airfoil. The pressure gradient dramatically increases, and the flow gets separated from the upstream of the airfoil. Upon lowering distance from the surface, static stall takes place at a higher point and a lower angle of attack, respectively.

References

Wieselsberger C. Wing resistance near the ground. National Advisory Committee for Aeronautics. 1922.

Rozhdestvensky KV. Matched asymptotics in aerodynamics of WIG vehicles. Proc. Intersociety High Performance Marine Vehicle and Exhibit HMP 92. 1992:17-27, June 24-27.

Rozhdestvensky KV. Wing-in-ground effect vehicles. Progress in Aerospace Sciences. 2006; 42(3): 211-283.

Daichin, Kang W, Zhao L. PIV measurements of the near-wake flow of an airfoil above a free surface. Journal of Hydrodynamics. 2007; 19(4): 482-487.

Djavareshkian MH, Esmaeli A, Parsania A. A comparison of smart and conventional flaps close to ground on aerodynamic performance. Journal of Aerosace Science and Technology. 2010; 7(2): 121-134.

Djavareshkian MH, Esmaeli A, Parsani A. Aerodynamics of smart flap under ground effect. Aerospace Science and Technology. 2011;15:642-652.

Pillai NS, Anil T, Aravind R, Vinod R, Kumar SE, Zaid ZU, Antony J, Manojkumar M. Investigation on airfoil operating in Ground Effect region. International Journal of Engineering & Technology. 2014; 3: 540.

Qu Q, Ju B, Huang L, Liu P, Agarwal RK. Flow physics of a multi-element airfoil in ground effect. In 54th AIAA Aerospace Sciences Meeting. 2016.

Qu Q, Lu Z, Liu P, Agarwal RK. Numerical study of aerodynamics of a wing-in-ground-effect craft. Journal of Aircraft. 2014; 51: 913-924.

Qu Q, Wang W, Liu P, Agarwal RK. Airfoil aerodynamics in ground effect for wide range of angles of attack. AIAA Journal. 2015; 53: 1048-1061.

Rostami A B, Ghadimi P, Ghasemi H. Adaptive viscous–inviscid interaction method for analysis of airfoils in ground effect. Journal of the Brazilian Society of Mechanical Sciences and Engineering. 2016; 38: 1593-1607.

Gao B, Qu Q, Agarwal RK, Aerodynamics of a transonic airfoil in ground effect. In 35th AIAA Applied Aerodynamics Conference. 2017.

He W, Guan Y, Theofilis V, Li LKB. Stability of low-reynolds-number separated flow around an airfoil near a wavy ground. AIAA Journal. 2019; 57: 29-34.

He W, Pérez JM, Yu P, Li LKB. Non-modal stability analysis of low-Re separated flow around a NACA 4415 airfoil in ground effect. Aerospace Science and Technology. 2019; 92: 269-279.

Esmaeilifar E, Djavareshkian MH, Feshalami BF, Esmaeili A. Hydrodynamic simulation of an oscillating hydrofoil near free surface in critical unsteady parameter. Ocean Engineering. 2017; 141: 227-236.

Menter FR. Two-equation eddy-viscosity turbulence models for engineering applications. AIAA Journal. 1994; 32: 1598-1605.

Tran M, Memon Z, Saieed A, Pao W, Hashim F. Numerical simulation of two-phase separation in T-junction with experimental validation. Journal of Mechanical Engineering and Sciences. 2018; 12: 4216-4230.

Memon Z, Pao W, Hashim F, Ahmed S. Experimental investigation of multiphase separation in different flow regimes through T-junction with an expander section. Journal of Mechanical Engineering and Sciences. 2019; 13: 5163 - 5181.

Saeid NH. Numerical predictions of sand erosion in a choke valve. Journal of Mechanical Engineering and Sciences. 2018; 12: 3988-4000.

Saieed A, Sam B, Pao W, Hashim FM. Numerical investigation of side arm gas volume fraction in two phase T-junction. Journal of Mechanical Engineering and Sciences. 2016; 10: 2311-2323.

Liang H, Wang X, Zou L, Zong Z. Numerical study of two-dimensional heaving airfoils in ground effect. Journal of Fluids and Structures. 2014; 48: 188-202.

Custodio D, Henoch C, Johari H. Aerodynamic characteristics of finite span wings with leading-edge protuberances. AIAA Journal. 2015; 53: 1878-1893.

Downloads

Published

2020-03-23

How to Cite

[1]
Y. Azargoon, M. H. Djavareshkian, and E. Esmaeilifar, “Effect of airfoil distance to water surface on static stall”, J. Mech. Eng. Sci., vol. 14, no. 1, pp. 6526–6537, Mar. 2020.

Similar Articles

<< < 2 3 4 5 6 7 8 9 10 11 > >> 

You may also start an advanced similarity search for this article.