Advanced search
Publication Cover
International Journal of Computational Fluid Dynamics Volume 28, 2014 - Issue 1-2
Submit an article Journal homepage
871
Views
18
CrossRef citations to date
0
Altmetric
Original Articles

Numerical study of gas-cyclone airflow: an investigation of turbulence modelling approaches

Tej P. DhakalDepartment of Mechanical Engineering, Mississippi State University, Mississippi State, MS39762, USA
,
D. Keith WaltersDepartment of Mechanical Engineering, Mississippi State University, Mississippi State, MS39762, USACorrespondence[email protected]
&
Wayne StrasserEastman Chemical Company, Kingsport, TN37662, USA
Pages 1-15 | Received 15 Aug 2013, Accepted 11 Dec 2013, Published online: 16 Jan 2014

References

  • ANSYS Inc. 2009. ANSYS FLUENT 12.0 Theory Guide.
  • Arolla, S.K., and P.A. Durbin. 2013. “Modeling Rotation and Curvature Effects Within Scalar Eddy Viscosity Framework.” International Journal of Heat and Fluid Flow 39: 78–89.
  • Barth, T.J., and D. Jespersen. 1989. “The Design and Application of Upwind Schemes on Unstructured Meshes.” Technical Report AIAA-89-0366, AIAA 27th Aerospace Sciences Meeting, Reno, Nevada.
  • Bhaskar, K.U., Y.R. Murthy, M.R. Raju, S. Tiwari, J.K. Srivastava, and N. Ramakrishnan. 2007. “CFD Simulation and Experimental Validation Studies on Hydrocyclone.” Minerals Engineering 20 (1): 60–71.
  • Bhushan, S., and D.K. Walters. 2012. “A Dynamic Hybrid RANS/LES Modeling Framework.” Physics of Fluids 24 (015103): 1–7.
  • Bloor, M.I.G., and D.B. Ingham. 1973. “Theoretical Investigation of the Flow in a Conical Hydrocyclone.” Transactions of the Institute of Chemical Engineers 51: 36–41.
  • Boysan, F., W.H. Ayers, and J. Swithenbank. 1982. “A Fundamental Mathematical Modelling Approach to Cyclone Design.” Transactions of the Institute of Chemical Engineers 60: 222–230.
  • Bradley, D. 1965. The Hydrocyclone. Oxford: Pergamon Press.
  • Chen, W., N. Zydek, and F. Parma. 2000. “Evaluation of Hydrocyclone Models for Practical Applications.” Chemical Engineering Journal 80 (1–3): 295–303.
  • Davailles, A., E. Climent, and F. Bourgeois. 2012. “Fundamental Understanding of Swirling Flow Pattern in Hydrocyclones.” Separation and Purification Technology 92: 152–160.
  • Davidson, M.R. 1988. “Numerical Calculations of Flow in a Hydrocyclone Operating without an Air Core.” Applied Mathematical Modelling 12: 119–128.
  • Delgadillo, J.A., and R.K. Rajamani. 2005 “A Comparative Study of Three Turbulence-Closure Models for the Hydrocyclone Problem.” International Journal of Mineral Processing 77 (4): 217–230.
  • Dhakal, T.P., and D.K. Walters. 2011. “A Three-Equation Variant of the SST k-ω Model Sensitized to Rotation and Curvature Effects.” ASME Journal of Fluids Engineering 133 (11): 1–9.
  • Durbin, P.A. 1991. “Near-Wall Turbulence Closure Modeling without Damping Functions.” Theoretical and Computational Fluid Dynamics 3: 1–13.
  • Dyakowski, T., and R.A. Williams. 1993. “Modelling Turbulent Flow Within a Small-Diameter Hydrocyclone.” Chemical Engineering Science 48 (6): 1143–1152.
  • Gronald, G., and J.J. Derksen. 2011. “Simulating Turbulent Swirling Flow in a Gas Cyclone: A Comparison of Various Modeling Approaches.” Powder Technology 205: 160–171.
  • He, P., M. Salcudean, and I.S. Gartshore. 1999. “A Numerical Simulation of Hydrocyclones.” Chemical Engineering Research and Design 77 (A5): 429–441.
  • Hellsten, A., and S. Wallin. 2009. “Explicit Algebraic Reynolds Stress and Non-Linear Eddy-Viscosity Models.” International Journal of Computational Fluid Dynamics 23 (4): 349–361.
  • Hoekstra, A.J., J.J. Derksen, and H.E.A. Van Den Akker. 1999. “An Experimental and Numerical Study of Turbulent Swirling Flow in Gas Cyclones.” Chemical Engineering Science 54: 2055–2056.
  • Hogg, S., and M.A. Leschziner. 1989. “Computation of Highly Swirling Confined Flow with a Reynolds Stress Turbulence Model.” AIAA Journal 27 (1): 57–63.
  • Hwang, C.C., H.Q. Shen, G. Zhu, and M.M. Khonsari. 1993. “On the Main Flow in Hydrocyclones.” ASME Journal of Fluids Engineering 115 (1): 21–25.
  • Jasak, H., H.G. Weller, and A.D. Gosman. 1999. “High Resolution NVD Differencing Scheme for Arbitrarily Unstructured Meshes.” International Journal for Numerical Methods in Fluids 31: 431–449.
  • Karimi, M., G. Akdogan, A. Dehghani, and S. Bradshaw. 2011. “Selection of Suitable Turbulence Models for Numerical Modelling of Hydrocyclones.” Chemical Product and Process Modeling 10 (1): 1–28.
  • Launder, B.E. 1989. “Second-Moment Closure and Its Use in Modeling Turbulent Industrial Flows.” International Journal for Numerical Methods for Fluids 9: 963–985.
  • Launder, B.E., and D.B. Spalding. 1972. Lectures in Mathematical Models in Turbulence. London: Academic Press.
  • Leonard, B.P. 1979. “A Stable and Accurate Convective Modelling Procedure Based on Quadratic Upstream Interpolation.” Computer Methods in Applied Mechanics and Engineering 19: 59–98.
  • Lien, F.S., and M.A. Leschziner. 1994. “Assessment of Turbulent Transport Models Including Non-Linear RNG Eddy-Viscosity Formulation and Second-Moment Closure.” Computers and Fluids 23 (8): 983–1004.
  • Lilly, D.K. 1992. “A Proposed Modification of the Germano Subgrid-Scale Closure Model.” Physics of Fluids 4: 633–635.
  • Meier, H.F., and M. Mori. 1999. “Anisotropic Behavior of the Reynolds Stress in Gas and Gas-solid Flows in Cyclones.” Powder Technology 101: 108–119.
  • Menter, F.R. 1994. “Two-Equation Eddy-Viscosity Turbulence Models for Engineering Applications.” AIAA Journal 32 (8): 1598–1605.
  • Menter, F.R. 2009. “Review of the Shear-Stress Transport Turbulence Model Experience from an Industrial Perspective.” International Journal of Computational Fluid Dynamics 23 (4): 305–316.
  • Nowakowski, A.F., J.C. Cullivan, R.A. Williams, and T. Dyakowski. 2004. “Application of CFD to Modelling of the Flow in Hydrocyclones. Is This a Realizable Option or Still a Research Challenge?” Minerals Engineering 17 (5): 661–669.
  • Obermair, S., C. Gutschi, J. Woisetschlager, and G. Staudinger. 2005. “Flow Pattern and Agglomeration in the Dust Outlet of a Gas Cyclone Investigated by Phase Doppler Anemometry.” Powder Technology 156: 34–42.
  • Patankar, S.V. 1980. Numerical Heat Transfer and Fluid Flow. Washington, DC: Hemisphere.
  • Pope, S.B. 2000. Turbulent Flows. Cambridge: Cambridge University Press.
  • Rotta, J.C. 1972. “Recent Attempts to Develop a Generally Applicable Calculation Method for Turbulent Shear Flow Layers.” AGARD Turbulent Shear Flows 11: 11–12.
  • Smagorinsky, J. 1963. “General Circulation Experiments with the Primitive Equations. I. The Basic Experiment.” Monthly Weather Review 91: 99–164.
  • Smirnov, P.E., and F.R. Menter. 2009. “Sensitization of the SST Turbulence Model to Rotation and Curvature by Applying the Spalart-Shur Correction Term.” ASME Journal of Turbomachinery 131 (4): 1–8.
  • Sommerfeld, M., and C.H. Ho. 2003. “Numerical Calculation of Particle Transport in Turbulent Wall Bounded Flows.” Powder Technology 131: 1–6.
  • Speziale, C.G., S. Sarkar, and T.B. Gatski. 1991. “Modelling the Pressure-Strain Correlation of Turbulence: An Invariant Dynamical Systems Approach.” Journal of Fluid Mechanics 227: 245–272.
  • Stephens, D.W., and K. Mohanarangam. 2010. “Turbulence Model Analysis of Flow Inside a Hydrocyclone.” Progress in Computational Fluid Dynamics 10 (5/6): 366–373.
  • Strasser, W. 2010. “Cyclone-Ejector Coupling and Optimisation.” Progress in Computational Fluid Dynamics 10 (1): 19–31.
  • Wallin, S., and A.V. Johansson. 2002. “Modelling Streamline Curvature Effects in Explicit Algebraic Reynolds Stress Turbulence Models.” International Journal of Heat and Fluid Flow 23: 721–730.
  • Walters, D.K., S. Bhushan, M.F. Alam, and D.S. Thompson. 2013. “Investigation of a Dynamic Hybrid RANS/LES Modelling Methodology for Finite-Volume CFD Simulations.” Flow, Turbulence and Combustion 91 (3): 643–667.
  • Wang, B., D.L. Xu, K.W. Chu, and A.B. Yu. 2006. “Numerical Study of Gas-Solid Flow in a Cyclone Separator.” Applied Mathematical Modelling 30: 1326–1342.
  • York, W.D., D.K. Walters, and J.H. Leylek. 2009. “A Simple and Robust Linear Eddy-Viscosity Formulation for Curved and Rotating Flows.” International Journal for Numerical Methods in Heat and Fluid Flow 19 (6): 745–776.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.