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Journal of Turbulence Volume 18, 2017 - Issue 10
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Original Articles

Investigating asymptotic suction boundary layers using a one-dimensional stochastic turbulence model

Moritz M. FragnerDepartment of Mechanical Engineering, Electrical and Energy Systems, BTU Cottbus-Senftenberg, Cottbus, GermanyCorrespondence[email protected]
&
Heiko SchmidtDepartment of Mechanical Engineering, Electrical and Energy Systems, BTU Cottbus-Senftenberg, Cottbus, Germany
Pages 899-928 | Received 03 Nov 2016, Accepted 23 May 2017, Published online: 13 Jun 2017

References

  • Kametani Y, Fukagata K, Örlü R., et al. Effect of uniform blowing/suction in a turbulent boundary layer at moderate Reynolds number. Int J Heat Fluid Flow. 2015;55:132–142.
  • Dutton R. The effects of distributed suction on the development of turbulent boundary layers. Cambridge: HM Stationary Office; 1958.
  • Antonia R, Fulachier L, Krishnamoorthy L, et al. Influence of wall suction on the organized motion in a turbulent boundary layer. J Fluid Mech. 1988;190:217–240.
  • Elena M. Suction effects on turbulence statistics in a heated pipe flow. Phys Fluids. 1984;27:861–866.
  • Yoshioka S, Alfredsson P. Control of turbulent boundary layers by uniform wall suction and blowing. In: Govindarajan R, editor. IUTAM Symposium on Laminar–Turbulent Transition. Netherlands: Springer; 2006. p. 437–442.
  • Khapko T, Schlatter P, Duguet Y, et al. Turbulence collapse in a suction boundary layer. J Fluid Mech. 2016;795:356–379.
  • Piomelli U. Model for large-eddy simulations of turbulent channel flows including transpiration [PhD thesis]. Stanford (CA): Stanford University; 1987.
  • Piomelli U, Ferziger J, Moin P, et al. New approximate boundary conditions for large eddy simulations of wall-bounded flows. Phys Fluids. 1989;A1:1061–1068.
  • Mariani P, Spalart P, Kollmann W. Direct simulation of a turbulent boundary layer with suction. In: So RMC, Speziale CG, Launder BE, editors. Near-wall turbulent flows. Amsterdam: Elsevier; 1993. p. 347–356.
  • Antonia R, Spalart P, Mariani P. Effect of suction on the near-wall anisotropy of a turbulent boundary-layer. Phys Fluids. 1994;6:430–432.
  • Sumitani Y, Kasagi N. Direct numerical-simulation of turbulent transport with uniform wall injection and suction. AIAA J. 1995;33:1220–1228.
  • Chung Y, Sung H. Initial relaxation of spatially evolving turbulent channel flow with blowing and suction. AIAA J. 2001;39:2091–2099.
  • Chung Y, Sung H, Krogstad P. Modulation of near-wall turbulence structure with wall blowing and suction. AIAA J. 2002;40:1529–1535.
  • Kametani Y, Fukagata K. Direct numerical simulation of spatially developing turbulent boundary layers with uniform blowing or suction. J Fluid Mech. 2011;681:154–172.
  • Schlatter P, Örlü R. Turbulent asymptotic suction boundary layers studied by simulation. In: 13th European Turbulence Conference (ETC13). Warsaw: IOP Publishing; 2011. p. 1–10. DOI: 10.1088/1742-6596/318/2/022020
  • Bobke A, Örlü R, Schlatter P. Simulations of turbulent asymptotic suction boundary layers. J Turbul. 2015;17:157–180.
  • Kerstein A. One-dimensional turbulence: model formulation and application to homogeneous turbulence, shear flows, and buoyant stratified flows. J Fluid Mech. 1999;392:277–334.
  • Kerstein A, Ashurst W, Wunsch S, et al. One-dimensional turbulence: vector formulation and application to free shear flows. J Fluid Mech. 2001;447:85–109.
  • Ashurst WT, Kerstein A. One-dimensional turbulence: variable-density formulation and application to mixing layers. Phys Fluids. 2005;17:025107-1--025107-26.
  • Schmidt R, A.R. K, Wunsch S, et al. Near-wall LES closure based on one-dimensional turbulence modeling. J Comput Phys. 2003;186:317–355.
  • Jozefik Z, Kerstein A, Schmidt H, et al. One-dimensional turbulence modeling of a turbulent counterflow flame with comparison to DNS. Combust Flame. 2015;162:2999–3015.
  • Hewson J, Kerstein A. Stochastic simulation of transport and chemical kinetics in turbulent CO/H2/N2 flames. Combust Theory Model. 2001;5:669–697.
  • Hewson J, Kerstein A. Local extinction and reignition in nonpremixed turbulent CO/H2/N2 jet flames. Combust. Sci. Technol. 2002;174:35–66.
  • Echekki T, Kerstein A, Dreeben T. One-dimensional turbulence simulation of turbulent jet diffusion flames: model formulation and illustrative applications. Combust Flame. 2001;125:1083–1105.
  • Movaghar A, Linne M, Oevermann M, et al. Numerical investigation of turbulent-jet primary breakup using one-dimensional turbulence. Int J Multiphase Flow. 2016;89:241–254 (accepted).
  • Schmidt H, Kerstein A, Ndlec R, et al. Analysis and numerical simulation of a laboratory analog of radiatively induced cloud-top entrainment, Theor Comp Fluid Dyn. 2013;27:377–395.
  • Schulz F, Glawe C, Schmidt H, et al. Toward modeling of CO2 multi-phase flow patterns using a stochastic multi-scale approach. Environ Earth Sci. 2013;70:3739–3748.
  • Lignell D, Kerstein A, Sun G, et al. Mesh adaption for efficient multiscale implementation of one-dimensional turbulence. Theor Comp Fluid Dyn. 2013;27:273–295.
  • Meiselbach F. Application of ODT to turbulent flow problems [PhD thesis]. Cottbus: BTU Cottbus-Senftenberg; 2015.
  • Schmidt R, Kerstein A, McDermott R. ODTLES: a multi-scale model for 3D turbulent flow based on one-dimensional turbulence modeling. Comput Methods Appl Mech Eng. 2010;199:865–880.
  • Gonzales-Juez E, Schmidt R, Kerstein A. ODTLES simulations of wall-bounded flows. Phys Fluids. 2011;23:125102-1--125102-13.
  • Glawe C, Schulz F, Gonzales-Juez E, et al. ODTLES simulations of turbulent flows through heated channels and ducts. Proceedings of TSFP-8; 2013. Aug 28--30; Poitiers, France; 2013.
  • Glawe C, Schmidt H, Kerstein A, et al. XLES. Part I: introduction to extended large eddy simulation. submitted to J Comput Phys. 2015.
  • Glawe C, Schmidt H, Kerstein A, et al. XLES Part II: from extended large eddy simulation to ODTLES. submitted to J Comput Phys. 2015.
  • Glawe C. ODTLES: turbulence modeling using a one-dimensional turbulence closed extended large eddy simulation approach [PhD thesis]. Berlin: Freie Universität Berlin; 2015.
  • Schlatter P, Örlü R. Assessment of direct numerical simulation data of turbulent boundary layers. J Fluid Mech. 2010;659:116–126.
  • Jozefik Z, Kerstein A, Schmidt H. Simulation of shock-turbulence interaction in non-reactive flow and in turbulent deflagration and detonation regimes using one-dimensional turbulence. Combust Flame. 2016;164:53–67.
  • Kerstein A. Linear-eddy modeling of turbulent transport. Part 6. microstructure of diffusive scalar mixing fields. J Fluid Mech. 1991;231:361–394.
  • Örlü R, Schlatter P. On the fluctuating wall-shear stress in zero pressure-gradient turbulent boundary layer flows. Phys Fluids. 2011;23:021704.

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