Numerical investigation of unsteady cavitating turbulent flows around a three-dimensional hydrofoil using stress-blended eddy simulation

Abstract

The mechanism of flow instability, which involves complex gas–liquid interactions and multiscale vortical structures, is one of the hot research areas in cavitating flow. The role of turbulence modeling is crucial in the numerical investigation of unsteady flow characteristics. Although large-eddy simulation (LES) has been used as a reliable numerical method, it is computationally costly. In this work, we used a hybrid Reynolds-averaged Navier–Stokes (RANS) and LES model, that is, stress-blended eddy simulation (SBES), to improve the prediction capability for the cloud cavitating flow. Our hybrid approach introduces a shielding function to integrate the RANS model with the LES applied only regionally, such as to large-scale separated flow regions. The results showed that the periodic shedding of cavity growth, break off, and collapse around a three-dimensional Clark-Y hydrofoil was reproduced in accordance with experimental observations. The lift/drag coefficients, streamwise velocity profiles, and cavity patterns obtained by the SBES model were in better agreement with the experimental data than those obtained by the modified RANS model. The re-entrant jet dynamics responsible for the break off of the attached cavity were discussed. Further analysis of vorticity transportation indicated that the stretching and dilatation terms dominated the development of vorticity around the hydrofoil. In conclusion, the SBES model can be used to predict cavitating turbulent flows in practical engineering applications.

Keywords

Unsteady cavitation stress-blended eddy simulation three-dimensional hydrofoil turbulence–cavitation interactions flow structure

Get full access to this article

View all access options for this article.

References

Wang

Cheng

, et al. Numerical investigation of unsteady cloud cavitating flow around the Clark-Y hydrofoil with adaptive mesh refinement using OpenFOAM. Ocean Eng 2017; 206: 107349.

Luo

Tsujimoto

. A review of cavitation in hydraulic machinery. J Hydrodyn 2016; 28: 335–358.

Gopalan

Katz

. Flow structure and modeling issues in the closure region of attached cavitation. Phys Fluids 2000; 12: 895–911.

Foeth

van-Terwisga

van-Doorne

. On the collapse structure of an attached cavity on a three-dimensional hydrofoil. J Fluids Eng 2008; 130: 071303.

Arabnejad

Amini

Farhat

, et al. Numerical and experimental investigation of shedding mechanisms from leading-edge cavitation. Int J Multiphse Flow 2019; 119: 123–143.

Coutier-Delgosha

Fortes-Patella

Reboud

. Evaluation of the turbulence model influence on the numerical simulations of unsteady cavitation. J Fluids Eng 2003; 125: 38.

Johansen

Shyy

. Filter-based unsteady RANS computations. Int J Multiphse Flow 2004; 25: 10–21.

Girimaji

Jeong

Srinivasan

. Partially averaged Navier-Stokes method for turbulence: fixed point analysis and comparison with unsteady partially averaged Navier-Stokes. J Appl Mech 2006; 73: 422.

Huang

Wang

Zhao

. Numerical simulation unsteady cloud cavitating flow with a filter-based density correction model. J Hydrodyn 2014; 26: 26–36.

10.

Huang

Zhao

Wang

. Large eddy simulation of turbulent vortex-cavitation interactions in transient sheet/cloud cavitating flows. Comput Fluids 2014; 92: 113–124.

11.

Luo

Arndt

REA

, et al. Large eddy simulation and theoretical investigations of the transient cavitating vortical flow structure around a NACA66 hydrofoil. Int J Multiphse Flow 2015; 68: 121–134.

12.

Bai

Cheng

, et al. Large eddy simulation of tip leakage cavitating flow focusing on cavitation-vortex interaction with Cartesian cut-cell mesh method. J Hydrodyn 2018; 30: 750–753.

13.

Roohi

Pendar

Rahimi

. Simulation of three-dimensional cavitation behind a disk using various turbulence and mass transfer models. Appl Math Modell 2016; 40: 542–564.

14.

Movahedian

Pasandidehfard

Roohi

. LES Investigation of sheet-cloud cavitation around a 3D twisted wing with a NACA 16012 hydrofoil. Ocean Eng 2019; 192: 106547.

15.

Long

, et al. Verification and validation of large eddy simulation of attached cavitating flow around a Clark-Y hydrofoil. Int J Multiphse Flow 2019; 115: 93–107.

16.

Zheng

Yan

Liu

, et al. Comparative assessment of SAS and DES turbulence modeling for massively separated flows. Acta Mech Sin 2015; 32: 12–21.

17.

Sedlar

Kratky

, et al. Numerical and experimental investigation of three-dimensional cavitating flow around the straight NACA2412 hydrofoil. Ocean Eng 2016; 123: 357–382.

18.

Huang

Wang

, et al. Detached-eddy simulation for time-dependent turbulent cavitating flows. Chin J Mech Eng 2012; 25: 484–490.

19.

Menter

Kuntz

. Adaptation of eddy-viscosity turbulence models to unsteady separated flow behind vehicles. The Aerodynamics of Heavy Vehicles: Trucks, Buses, and Trains. Berlin: Heidelberg, 2004, p.339–352.

20.

Walters

Bhushan

Alam

, et al. Investigation of a dynamic hybrid RANS/LES modelling methodology for finite-volume CFD simulations. Flow, Turbul Combust 2013; 91: 643–667.

21.

Cai

Liu

. Comparative study of scale-resolving simulations for marine-propeller unsteady flows. Int Commun Heat Mass Transf 2019; 100: 1–11.

22.

Liu

, et al. Scale-resolving simulation and particle image velocimetry validation of the flow around a marine propeller. J Zhejiang Univ-SCI A 2019, 20: 553–563.

23.

Liu

, et al. Application of scale-resolving simulation to a hydraulic coupling, a hydraulic retarder, and a hydraulic torque converter. J Zhejiang Univ-SCI A 2018; 19: 904–925.

24.

Liu

, et al. Stress-blended eddy simulation of the turbulent flow around circular cylinder with dynamic hybrid RANS/LES model. J Beijing Inst Technol 2019; 28: 238–247.

25.

Liu

, et al. Scale-resolving simulation of thermal flow and accurate performance prediction in hydrodynamic torque converter. Jixie Gongcheng Xuebao, 2018; 54: 146–153. (In Chinese)

26.

Zwart

Gerber

Belamri

. A two-phase flow model for predicting cavitation dynamics. In 5th International Conference on Multiphase Flow, Yokohama, Japan, 2004.

27.

Yakhot

Orszag

. Renormalization group analysis of turbulence. I. Basic theory. J Sci Comput 1986; 1: 3–51.

28.

Reboud

Stutz

Coutier-Delgosha

. Two phase flow structure of cavitation: experiment and modeling of unsteady effects. In: 3rd Symposium on Cavitation, Grenoble, France, 1998.

29.

Wang

Senocak

Shyy

, et al. Dynamics of attached turbulent cavitating flows. Prog Aeosp Sci 2001; 37: 551–581.

30.

Sagaut

. Large eddy simulation for incompressible flows: an introduction. Berlin: Springer, 2006.

31.

Luo

Huang

. Transient cavitating vortical flows around a hydrofoil using k-ω partially averaged Navier–Stokes model. Mod Phys Lett B 2016; 30: 1550262.

32.

Long

Cheng

, et al. Numerical investigation of attached cavitation shedding dynamics around the Clark-Y hydrofoil with the FBDCM and an integral method. Ocean Eng 2017; 137: 247–261.

33.

Chen

. Numerical investigation of the compressible flow past an aerofoil. J Fluid Mech 2009; 643: 97–126.

34.

Huang

Young

Wang

, et al. Combined experimental and computational investigation of unsteady structure of sheet/cloud cavitation. J Fluid Eng 2013, 135: 071301.

35.

Pope

. Turbulent flows. Cambridge, UK: Cambridge University Press, 2000.

36.

Dubief

Delcayre

. On coherent-vortex identification in turbulence. J Turbul 2000, 1: N11.

37.

Dittakavi

Chunekar

Frankel

. Large eddy simulation of turbulent-cavitation interactions in a Venturi nozzle. J Fluid Eng 2010; 132: 121301.

38.

Long

, et al. Large eddy simulation of turbulent attached cavitating flow with special emphasis on large scale structures of the hydrofoil wake and turbulence-cavitation interactions. J Hydrodyn 2017; 29: 27–39.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.02 MB