flow_types

Cases by Flow Type

Click on the flow type buttons below to expand/collapse lists of flows in each category.

Homogeneous Flows

  • case014 (Homogeneous Curved Flow)
  • case039 (Rotating Homogeneous Turbulence in Axisymmetric Contraction)
  • case047 (Homogeneous Isotropic Flow with/without Mean Temperature Gradient)
  • case048 (Homogeneous Isotropic Decay of Passive Scalar Fluctuations)
  • case049 (Homogeneous Turbulent Shear Flows)

Mixing Layers

Jets

  • case026 (Single-Stream Swirling Jet in Still Air)
  • case038 (Circular air jet)

Wakes

  • case003 (Plane Wake after a Circular Cylinder)
  • case011 (Airfoil Boundary Layer and Wake)
  • case035 (Low Reynolds Number Turbulent Flow Near Wakes)
  • case040 (Plane Wake Near a Swept Wing)
  • case061 (Wake of a streamwise axially rotating cylinder)
  • case068 (Near-wake flow of a V-gutter with slit bleed)

Curvature/Rotation

  • case014 (Homogeneous Curved Flow)
  • case024 (Stably Curved Mixing Layer)
  • case039 (Rotating Homogeneous Turbulence in Axisymmetric Contraction)

Unsteady Flow

  • case061 (Wake of a streamwise axially rotating cylinder)

Temperature/Scalar Field

  • case003 (Plane Wake after a Circular Cylinder)
  • case047 (Homogeneous Isotropic Flow with/without Mean Temperature Gradient)
  • case048 (Homogeneous Isotropic Decay of Passive Scalar Fluctuations)

Two-Dimensional Flows

  • case011 (Airfoil Boundary Layer and Wake)
  • case015 (Transitional Cascade Flow)
  • case043 (Vortex Shedding Past Square Cylinder)
  • case078 (Flow through staggered tube bundle)
  • case080 (Steady flow past tube bundles)
  • case086 (Surface pressure in normal triangular tube arrays)
  • case087 (Flow and deflection measurements of FSI-induced oscillation of two rigid structures in turbulent flows)
  • case088 (Combined flow and deformation measurements of FSI-induced oscillation of a bluff flexible structure in uniform flows)

Three-Dimensional Flows

  • case008 (Wing-Body Junction with Separation)
  • case027 (Infinite 35 degree swept wing)
  • case040 (Plane Wake Near a Swept Wing)
  • case041 (Flow Around Surface-Mounted Cubical Obstacle)
  • case063 (Wing-body junction flow)
  • case074 (Flow around inclined prolate spheroid)
  • case082 (Flow around a simplified car body (Ahmed body))
  • case084 (Turbulent boundary layer over a cube)

Flows Around Streamlined Bodies

  • case011 (Airfoil Boundary Layer and Wake)
  • case015 (Transitional Cascade Flow)
  • case027 (Infinite 35 degree swept wing)
  • case040 (Plane Wake Near a Swept Wing)

Flows Around Bluff Bodies

  • case043 (Vortex Shedding Past Square Cylinder)
  • case074 (Flow around inclined prolate spheroid)
  • case078 (Flow through staggered tube bundle)
  • case080 (Steady flow past tube bundles)
  • case082 (Flow around a simplified car body (Ahmed body))
  • case086 (Surface pressure in normal triangular tube arrays)
  • case087 (Flow and deflection measurements of FSI-induced oscillation of two rigid structures in turbulent flows)
  • case088 (Combined flow and deformation measurements of FSI-induced oscillation of a bluff flexible structure in uniform flows)

Flow Through Tube Bundles/Arrays

  • case078 (Flow through staggered tube bundle)
  • case080 (Steady flow past tube bundles)
  • case086 (Surface pressure in normal triangular tube arrays)

Unsteady Flows

  • case043 (Vortex Shedding Past Square Cylinder)
  • case087 (Flow and deflection measurements of FSI-induced oscillation of two rigid structures in turbulent flows)
  • case088 (Combined flow and deformation measurements of FSI-induced oscillation of a bluff flexible structure in uniform flows)

Fluid-Structure Interaction

  • case087 (Flow and deflection measurements of FSI-induced oscillation of two rigid structures in turbulent flows)
  • case088 (Combined flow and deformation measurements of FSI-induced oscillation of a bluff flexible structure in uniform flows)

Two-Dimensional Boundary Layers

  • case005 (Unsteady Boundary Layer)
  • case009 (Natural Convection Boundary Layer)
  • case016 (Horizontal Convective Boundary Layer)
  • case019 (Boundary Layer with Adverse Pressure Gradient)
  • case020 (Flat Plate Transitional Boundary Layers)
  • case021 (Sink Flow Boundary Layer)
  • case029 (Time-Periodic Boundary Layer)
  • case033 (Constant-Pressure Boundary Layer)
  • case050 (Boundary layer on the verge of separation)
  • case054 (Upslope and vertical convective boundary layer)
  • case073 (Flat plate transitional boundary layer)
  • case085 (Turbulent Stokes boundary layer)

Three-Dimensional Boundary Layers

  • case012 (Vortices in Boundary Layer)
  • case017 (Laterally Strained Boundary Layers)
  • case028 (Pseudo-Ekman Boundary Layer)
  • case051 (Boundary layer in an S-shaped channel)
  • case057 (3-Dimensional Boundary Layer Generated by a Spinning body)
  • case066 (Strained flow over a streamwise axially rotating cylinder)
  • case067 (Flow along a streamwise axially rotating cylinder)

Flows Around/Over Bodies

  • case008 (Wing-Body Junction with Separation)
  • case041 (Flow Around Surface-Mounted Cubical Obstacle)
  • case042 (Flows over 3D and 2D Hills)
  • case063 (Wing-body junction flow)
  • case064 (Flow approaching a wall-mounted circular cylinder)
  • case069 (Flow over isolated 2D hill)
  • case084 (Turbulent boundary layer over a cube)

Transitional Flows

  • case020 (Flat Plate Transitional Boundary Layers)
  • case073 (Flat plate transitional boundary layer)

Flows With Separation

Flows with Curvature/Rotation

  • case051 (Boundary layer in an S-shaped channel)
  • case065 (Turning flow over a flat plate)

Jets

  • case025 (Normally Impinging Jet from a Circular Nozzle)
  • case055 (2D plane turbulent wall jet)

Unsteady Flows

  • case005 (Unsteady Boundary Layer)
  • case029 (Time-Periodic Boundary Layer)
  • case085 (Turbulent Stokes boundary layer)

Flows with Scalar/Temperature/Heat Transfer

  • case009 (Natural Convection Boundary Layer)
  • case016 (Horizontal Convective Boundary Layer)
  • case025 (Normally Impinging Jet from a Circular Nozzle)
  • case042 (Flows over 3D and 2D Hills)
  • case054 (Upslope and vertical convective boundary layer)

Buoyant Flows

  • case009 (Natural Convection Boundary Layer)
  • case016 (Horizontal Convective Boundary Layer)
  • case054 (Upslope and vertical convective boundary layer)

Two-Dimensional Flows

  • case010 (Couette Flow with Fixed Wavy Wall)
  • case018 (2D Model Hill Flows)
  • case022 (Boundary Layer in and Downstream from Convex Curvature)
  • case023 (Boundary Layer in a Concave Bend)
  • case030 (Backward-Facing Step with Inclined Opposite Wall)
  • case031 (Backward-Facing Step)
  • case053 (Backward-facing inclined step)
  • case056 (Backward-facing step with uniform normal bleed)
  • case076 (Flow over a wavy wall)
  • case077 (Separated turbulent flow over a wavy wall)
  • case078 (Flow through staggered tube bundle)
  • case079 (Turbulent natural convection in an enclosed tall cavity)
  • case080 (Steady flow past tube bundles)
  • case081 (Flow over Periodic Hills)
  • case083 (Wall-mounted two-dimensional hump with oscillatory zero-mass-flux jet or suction through a slot)
  • case086 (Surface pressure in normal triangular tube arrays)

Three-Dimensional Flows

  • case004 (Swirling and Non-Swirling Flows in Curved Pipe)
  • case006 (Square-Sectioned Duct 180 degree Bend)
  • case013 (Sudden Pipe Expansion)
  • case017 (Laterally Strained Boundary Layers)
  • case052 (Duct flows with smooth and rough walls)
  • case062 (Developing flow in curved rectangular duct)
  • case091 (Thermal boundary layers in turbulent Rayleigh-Benard convection at aspect ratios between 1 and 9)
  • case094 (Local and time-resolved wall heat flux in turbulent Rayleigh-Benard convection)

Channel Flows

  • case032 (Channel Flow)
  • case036 (Couette Flow with Plane Fixed Wall)
  • case037 (Pulsed Channel Flow)
  • case044 (2D Channel Flow with/without Scalar Transport)
  • case045 (2D Chanel Flow with/without Thermal Field)
  • case046 (Couette Flow with Plane Fixed Wall)
  • case071 (Turbulent plane Couette flow)

Pipes/Ducts with Constant Cross-Section

  • case004 (Swirling and Non-Swirling Flows in Curved Pipe)
  • case006 (Square-Sectioned Duct 180 degree Bend)
  • case032 (Channel Flow)
  • case036 (Couette Flow with Plane Fixed Wall)
  • case037 (Pulsed Channel Flow)
  • case044 (2D Channel Flow with/without Scalar Transport)
  • case045 (2D Chanel Flow with/without Thermal Field)
  • case046 (Couette Flow with Plane Fixed Wall)
  • case052 (Duct flows with smooth and rough walls)
  • case062 (Developing flow in curved rectangular duct)
  • case071 (Turbulent plane Couette flow)
  • case072 (Turbulent pipe flow with swirl)
  • case093 (The CoLaPipe - The new Cottbus large pipe test facility at Brandenburg University of Technology)

Pipes/Ducts with Varying Cross-Section

  • case010 (Couette Flow with Fixed Wavy Wall)
  • case013 (Sudden Pipe Expansion)
  • case017 (Laterally Strained Boundary Layers)
  • case018 (2D Model Hill Flows)
  • case030 (Backward-Facing Step with Inclined Opposite Wall)
  • case031 (Backward-Facing Step)
  • case053 (Backward-facing inclined step)
  • case056 (Backward-facing step with uniform normal bleed)
  • case058 (Pipe constriction)
  • case060 (Swirling boundary layer in a conical diffuser)
  • case075 (Flow through axisymmetric expansions)
  • case076 (Flow over a wavy wall)
  • case077 (Separated turbulent flow over a wavy wall)
  • case081 (Flow over Periodic Hills)
  • case083 (Wall-mounted two-dimensional hump with oscillatory zero-mass-flux jet or suction through a slot)

Separated Flows

  • case013 (Sudden Pipe Expansion)
  • case018 (2D Model Hill Flows)
  • case030 (Backward-Facing Step with Inclined Opposite Wall)
  • case031 (Backward-Facing Step)
  • case053 (Backward-facing inclined step)
  • case056 (Backward-facing step with uniform normal bleed)
  • case058 (Pipe constriction)
  • case075 (Flow through axisymmetric expansions)
  • case076 (Flow over a wavy wall)
  • case077 (Separated turbulent flow over a wavy wall)
  • case078 (Flow through staggered tube bundle)
  • case080 (Steady flow past tube bundles)
  • case081 (Flow over Periodic Hills)
  • case083 (Wall-mounted two-dimensional hump with oscillatory zero-mass-flux jet or suction through a slot)
  • case086 (Surface pressure in normal triangular tube arrays)

Swirling Flows

  • case001 (Isothermal Dump Combustor With Swirl)
  • case004 (Swirling and Non-Swirling Flows in Curved Pipe)
  • case060 (Swirling boundary layer in a conical diffuser)
  • case072 (Turbulent pipe flow with swirl)

Flows with Curvature/Rotation

  • case004 (Swirling and Non-Swirling Flows in Curved Pipe)
  • case006 (Square-Sectioned Duct 180 degree Bend)
  • case022 (Boundary Layer in and Downstream from Convex Curvature)
  • case023 (Boundary Layer in a Concave Bend)
  • case062 (Developing flow in curved rectangular duct)

Unsteady Flows

  • case037 (Pulsed Channel Flow)
  • case083 (Wall-mounted two-dimensional hump with oscillatory zero-mass-flux jet or suction through a slot)

Flows with Scalar/Temperature/Heat Transfer

  • case044 (2D Channel Flow with/without Scalar Transport)
  • case045 (2D Chanel Flow with/without Thermal Field)
  • case079 (Turbulent natural convection in an enclosed tall cavity)
  • case090 (Viscous boundary layers in turbulent Rayleigh-Benard convection)
  • case091 (Thermal boundary layers in turbulent Rayleigh-Benard convection at aspect ratios between 1 and 9)
  • case094 (Local and time-resolved wall heat flux in turbulent Rayleigh-Benard convection)

Buoyant Flows

  • case079 (Turbulent natural convection in an enclosed tall cavity)
  • case090 (Viscous boundary layers in turbulent Rayleigh-Benard convection)
  • case091 (Thermal boundary layers in turbulent Rayleigh-Benard convection at aspect ratios between 1 and 9)
  • case094 (Local and time-resolved wall heat flux in turbulent Rayleigh-Benard convection)