UFR 3-35 References: Difference between revisions
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* Apsilidis, N., Diplas, P., Dancey, C. L., and Bouratsis, P. (2015). Time-resolved flow dynamics and Reynolds number effects at a wall-cylinder junction. ''Journal of Fluid Mechanics'' 776:475-511. | * Apsilidis, N., Diplas, P., Dancey, C. L., and Bouratsis, P. (2015). Time-resolved flow dynamics and Reynolds number effects at a wall-cylinder junction. ''Journal of Fluid Mechanics'' 776:475-511. | ||
* Baghbadorani, D. A., Beheshti, A. & Ataie-Ashtiani, B. (2017) Scour hole depth prediction around pile groups: review, comparison of existing methods, and proposition of a new approach. ''Natural Hazards'' 88(2), 977-1001. | |||
* Baker, C. J. (1980) The turbulent horseshoe vortex. ''Journal of wind engineering and industrial aerodynamics'' 6, 9-23. | |||
* Dargahi, B. (1989). The turbulent flow field around a circular cylinder. ''Experiments in Fluids'' 8(1-2):1-12. | * Dargahi, B. (1989). The turbulent flow field around a circular cylinder. ''Experiments in Fluids'' 8(1-2):1-12. | ||
* Devenport, W. J. and Simpson, R. L. (1990). Timedependent and time-averaged turbulence structure near the nose of a wing-body junction. ''Journal of Fluid Mechanics'' 210:23-55. | * Devenport, W. J. and Simpson, R. L. (1990). Timedependent and time-averaged turbulence structure near the nose of a wing-body junction. ''Journal of Fluid Mechanics'' 210:23-55. | ||
* Escauriaza, C. and Sotiropoulos, F. (2011). Reynolds Number Effects on the Coherent Dynamics of the Turbulent Horseshoe Vortex System. ''Flow, Turbulence and Combustion'' 86(2):231-262. | * Escauriaza, C. and Sotiropoulos, F. (2011). Reynolds Number Effects on the Coherent Dynamics of the Turbulent Horseshoe Vortex System. ''Flow, Turbulence and Combustion'' 86(2):231-262. | ||
* Ettema, R., Kirkil, G. & Muste, M. (2006) Similitude of Large-Scale Turbulence in Experiments on Local Scour at Cylinders. ''Journal of Hydraulic Engineering'' 132(1),33-40. | |||
* Jenssen, U. (2019). Experimental Study of the Flow Around a Scouring Bridge Pier. PhD thesis, Technische Universität München, München. | * Jenssen, U. (2019). Experimental Study of the Flow Around a Scouring Bridge Pier. PhD thesis, Technische Universität München, München. | ||
* Kirkil, G. and Constantinescu, G. (2015). Effects of cylinder Reynolds number on the turbulent horseshoe vortex system and near wake of a surface-mounted circular cylinder. ''Physics of Fluids'' 27(7). | * Kirkil, G. and Constantinescu, G. (2015). Effects of cylinder Reynolds number on the turbulent horseshoe vortex system and near wake of a surface-mounted circular cylinder. ''Physics of Fluids'' 27(7). | ||
* Laursen, E. M. & Toch, A. (1956) Scour around bridge piers and abutements. Tech. Rep. ''Iowa Institute of Hydraulic Research''. | |||
* Link, O., Pfleger, F. & Zanke, U. (2008) Characteristics of developping scour-holes at sand-embedded cylinder. ''International Journal of Sediment Research'' 23, 258-266. | |||
* Manhart, M. (2004) A zonal grid algorithm for DNS of turbulent boundary layers. ''Computers and Fluids'' 33(3):435–461. | * Manhart, M. (2004) A zonal grid algorithm for DNS of turbulent boundary layers. ''Computers and Fluids'' 33(3):435–461. | ||
* Martinuzzi, R. & Tropea, C. (1993) The Flow Around Surface-Mounted, Prismatic Obstacles Placed in a Fully Developed Channel Flow. ''Journal of Fluids Engineering'' 115(1),85-92. | |||
* Melville, B. W. & Raudkivi, A. J. (1977) Flow characteristics in local scour at bridge piers. ''Journal of Hydraulic Research'' 15(4), 373-380. | |||
* Nicoud, F. & Ducros, F. (1999). Subgrid-scale stress modelling based on the square of the velocity gradient tensor. ''Flow, Turbulence and Combustion'' 62(3):183–200. | * Nicoud, F. & Ducros, F. (1999). Subgrid-scale stress modelling based on the square of the velocity gradient tensor. ''Flow, Turbulence and Combustion'' 62(3):183–200. | ||
* Paik, J., Escauriaza, C., and Sotiropoulos, F. (2007). On the bimodal dynamics of the turbulent horseshoe vortex system in a wing-body junction. ''Physics of Fluids'' (19):045107. | * Paik, J., Escauriaza, C., and Sotiropoulos, F. (2007). On the bimodal dynamics of the turbulent horseshoe vortex system in a wing-body junction. ''Physics of Fluids'' (19):045107. | ||
* Peller, N. (2010). Numerische Simulation turbulenter Strömungen mit Immersed Boundaries. PhD thesis, Technische Universität München, München. | * Peller, N. (2010). Numerische Simulation turbulenter Strömungen mit Immersed Boundaries. PhD thesis, Technische Universität München, München. | ||
* Peller, N., Duc, A. L., Tremblay, F. & Manhart, M. (2006) High-order stable interpolations for immersed boundary methods. ''International Journal of Numerical Methods in Fluids'' 52:1175–1193. | * Peller, N., Duc, A. L., Tremblay, F. & Manhart, M. (2006) High-order stable interpolations for immersed boundary methods. ''International Journal of Numerical Methods in Fluids'' 52:1175–1193. | ||
* Pfleger, F. 2011 Experimentelle Untersuchung der Auskolkung um einen zylindrischen | * Pfleger, F. (2011) Experimentelle Untersuchung der Auskolkung um einen zylindrischen Brückenpfeiler. PhD thesis in german, Technical University of Munich, Germany. | ||
Brückenpfeiler. PhD thesis in german, Technical University of Munich, Germany. | * Roulund, A., Mutlu Sumer, B., Fredsoe, J. & Michelsen, J. (2005) Numerical and experimental investigation of flow and scour around a circular pile. ''Journal of Fluid Mechanics'' 534, 351-401. | ||
* Schanderl, W. (2018). Large-Eddy Simulation of the flow around a wall-mounted cylinder. PhD thesis, Technische Universität München, München. | * Schanderl, W. (2018). Large-Eddy Simulation of the flow around a wall-mounted cylinder. PhD thesis, Technische Universität München, München. | ||
* Schanderl, W., Jenssen, U., and Manhart, M. (2017a). Near-wall stress balance in front of a wall-mounted cylinder. ''Flow, Turbulence and Combustion'' 99(3-4):665–684. | * Schanderl, W., Jenssen, U., and Manhart, M. (2017a). Near-wall stress balance in front of a wall-mounted cylinder. ''Flow, Turbulence and Combustion'' 99(3-4):665–684. | ||
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* Schanderl, W. and Manhart, M. (2016). Reliability of wall shear stress estimations of the flow around a wall-mounted cylinder. ''Computers and Fluids'' 128:16-29. | * Schanderl, W. and Manhart, M. (2016). Reliability of wall shear stress estimations of the flow around a wall-mounted cylinder. ''Computers and Fluids'' 128:16-29. | ||
* Schanderl, W. and Manhart, M. (2018). Dissipation of Turbulent Kinetic Energy in a Cylinder Wall Junction Flow. ''Flow, Turbulence and Combustion'' 101(2):499–519. | * Schanderl, W. and Manhart, M. (2018). Dissipation of Turbulent Kinetic Energy in a Cylinder Wall Junction Flow. ''Flow, Turbulence and Combustion'' 101(2):499–519. | ||
* Simpson, R. L. (2001). Junction Flows. Annual Review of Fluid Mechanics, 33:415-443. | * Simpson, R. L. (2001). Junction Flows. ''Annual Review of Fluid Mechanics'', 33:415-443. | ||
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Revision as of 14:16, 11 October 2019
Cylinder-wall junction flow
Underlying Flow Regime 3-35
References
- Apsilidis, N., Diplas, P., Dancey, C. L., and Bouratsis, P. (2015). Time-resolved flow dynamics and Reynolds number effects at a wall-cylinder junction. Journal of Fluid Mechanics 776:475-511.
- Baghbadorani, D. A., Beheshti, A. & Ataie-Ashtiani, B. (2017) Scour hole depth prediction around pile groups: review, comparison of existing methods, and proposition of a new approach. Natural Hazards 88(2), 977-1001.
- Baker, C. J. (1980) The turbulent horseshoe vortex. Journal of wind engineering and industrial aerodynamics 6, 9-23.
- Dargahi, B. (1989). The turbulent flow field around a circular cylinder. Experiments in Fluids 8(1-2):1-12.
- Devenport, W. J. and Simpson, R. L. (1990). Timedependent and time-averaged turbulence structure near the nose of a wing-body junction. Journal of Fluid Mechanics 210:23-55.
- Escauriaza, C. and Sotiropoulos, F. (2011). Reynolds Number Effects on the Coherent Dynamics of the Turbulent Horseshoe Vortex System. Flow, Turbulence and Combustion 86(2):231-262.
- Ettema, R., Kirkil, G. & Muste, M. (2006) Similitude of Large-Scale Turbulence in Experiments on Local Scour at Cylinders. Journal of Hydraulic Engineering 132(1),33-40.
- Jenssen, U. (2019). Experimental Study of the Flow Around a Scouring Bridge Pier. PhD thesis, Technische Universität München, München.
- Kirkil, G. and Constantinescu, G. (2015). Effects of cylinder Reynolds number on the turbulent horseshoe vortex system and near wake of a surface-mounted circular cylinder. Physics of Fluids 27(7).
- Laursen, E. M. & Toch, A. (1956) Scour around bridge piers and abutements. Tech. Rep. Iowa Institute of Hydraulic Research.
- Link, O., Pfleger, F. & Zanke, U. (2008) Characteristics of developping scour-holes at sand-embedded cylinder. International Journal of Sediment Research 23, 258-266.
- Manhart, M. (2004) A zonal grid algorithm for DNS of turbulent boundary layers. Computers and Fluids 33(3):435–461.
- Martinuzzi, R. & Tropea, C. (1993) The Flow Around Surface-Mounted, Prismatic Obstacles Placed in a Fully Developed Channel Flow. Journal of Fluids Engineering 115(1),85-92.
- Melville, B. W. & Raudkivi, A. J. (1977) Flow characteristics in local scour at bridge piers. Journal of Hydraulic Research 15(4), 373-380.
- Nicoud, F. & Ducros, F. (1999). Subgrid-scale stress modelling based on the square of the velocity gradient tensor. Flow, Turbulence and Combustion 62(3):183–200.
- Paik, J., Escauriaza, C., and Sotiropoulos, F. (2007). On the bimodal dynamics of the turbulent horseshoe vortex system in a wing-body junction. Physics of Fluids (19):045107.
- Peller, N. (2010). Numerische Simulation turbulenter Strömungen mit Immersed Boundaries. PhD thesis, Technische Universität München, München.
- Peller, N., Duc, A. L., Tremblay, F. & Manhart, M. (2006) High-order stable interpolations for immersed boundary methods. International Journal of Numerical Methods in Fluids 52:1175–1193.
- Pfleger, F. (2011) Experimentelle Untersuchung der Auskolkung um einen zylindrischen Brückenpfeiler. PhD thesis in german, Technical University of Munich, Germany.
- Roulund, A., Mutlu Sumer, B., Fredsoe, J. & Michelsen, J. (2005) Numerical and experimental investigation of flow and scour around a circular pile. Journal of Fluid Mechanics 534, 351-401.
- Schanderl, W. (2018). Large-Eddy Simulation of the flow around a wall-mounted cylinder. PhD thesis, Technische Universität München, München.
- Schanderl, W., Jenssen, U., and Manhart, M. (2017a). Near-wall stress balance in front of a wall-mounted cylinder. Flow, Turbulence and Combustion 99(3-4):665–684.
- Schanderl, W., Jenssen, U., Strobl, C., and Manhart, M. (2017b). The structure and budget of turbulent kinetic energy in front of a wall-mounted cylinder. Journal of Fluid Mechanics 827:285-321.
- Schanderl, W. and Manhart, M. (2016). Reliability of wall shear stress estimations of the flow around a wall-mounted cylinder. Computers and Fluids 128:16-29.
- Schanderl, W. and Manhart, M. (2018). Dissipation of Turbulent Kinetic Energy in a Cylinder Wall Junction Flow. Flow, Turbulence and Combustion 101(2):499–519.
- Simpson, R. L. (2001). Junction Flows. Annual Review of Fluid Mechanics, 33:415-443.
Contributed by: Ulrich Jenssen, Wolfgang Schanderl, Michael Manhart — Technical University Munich
© copyright ERCOFTAC 2019