Database Projects

2021

DNS of Turbulent Heat Transfer in Impinging Jets at Different Reynolds and Prandtl Numbers.
Secchi, F.; Magagnato, F.
2021, February 15. doi:10.5445/IR/1000129589

2020

Coupled Simulation of Flow-Induced Viscous and Elastic Anisotropy of Short-Fiber Reinforced Composites.
Karl, T.; Gatti, D.
2020, November 24. doi:10.5445/IR/1000126534

Coupled Simulation of Flow-Induced Viscous and Elastic Anisotropy of Short-Fiber Reinforced Composites.
Karl, T.; Gatti, D.
2020, September 8. doi:10.5445/IR/1000123343

Coupled Simulation of Flow-Induced Viscous and Elastic Anisotropy of Short-Fiber Reinforced Composites.
Karl, T.; Gatti, D.
2020, May 12. doi:10.5445/IR/1000119139

2019

Dataset for rearrangement of secondary flow over spanwise heterogeneous roughness.
Stroh, A.; Schäfer, K.; Frohnapfel, B.; Forooghi, P.
2019. doi:10.5445/IR/1000100142

Thermal statistics of turbulent forced convection pipe flow for axially and azimuthally inhomogeneous thermal boundary conditions.
Straub, S.
2019. doi:10.5445/IR/1000100008

Statistics on turbulent forced convection pipe flow with different thermal boundary conditions for two Prandtl numbers.
Straub, S.
2019. doi:10.5445/IR/1000096346

Dataset to "Flow stages during vortex decay in an impulsively stopped rotating cylinder".
Kaiser, F.
2019. doi:10.5445/IR/1000094344

Thermal Statistics of Turbulent Forced Convection Pipe Flow for Azimuthally Inomogeneous Thermal Boundary Conditions.
Straub, S.
2019. doi:10.5445/IR/1000093905

Riblets in fully developed turbulent channel flow.
Deyn, L. H. von; Gatti, D.; Frohnapfel, B.
2019. doi:10.5445/IR/1000089978

2018

Flow statistics of spatially developing turbulent boundary layers with localized application of three different control techniques aimed at reduction of skin friction drag.
Stroh, A.
2018. doi:10.5445/IR/1000087742

2017

Turbulent flow statistics at Constant Power Input (CPI) with and without drag reduction.
Gatti, D.
2017. doi:10.5445/IR/1000087559

Database Projects
Title	Contact	Short Description
Active Control of Spatially Developing Turbulent Boundary Layers	Alexander Stroh	Simulations of spatially developing turbulent boundary layers with localized application of three different control techniques aimed at reduction of skin friction drag. Considered control techniques are uniform blowing, body-force damping of wall-normal velocity component and opposition control.
DFG Priority Programme 1881 "Turbulent Superstructures"	Davide Gatti	3d data set and Lagrangian particles trajectories.
DNS of momentum and heat transfer over rough walls	Pourya Forooghi	Simulations of flow and heat tranfer (passive scalar) in fully developed channals over a variety of roughness geometries.
Turbulent flow over superhydrophobic surfaces with streamwise grooves	Alexander Stroh	Simulations of superhydrophobic surfaces modelled by imposition of slip / no-slip boundary conditions at the wall in a fully developed turbulent channel flow at Reτ=180. Original manuscript: https://doi.org/10.1017/jfm.2014.137