High-speed vehicles experience a highly challenging environment in which the freestream Mach number and surface temperature greatly influence aerodynamic drag and heat transfer. The interplay of these two parameters strongly affects the near-wall dynamics of high-speed turbulent boundary layers (TBLs) in a non-trivial way, breaking similarity arguments on velocity and temperature fields, typically derived for adiabatic cases. We present direct numerical simulations of flat-plate zero-pressure-gradient TBLs spanning three freestream Mach numbers [2,4,6] [ 2 , 4 , 6 ] and four wall temperature conditions (from adiabatic to very cold walls), emphasising the choice of the wall-cooling parameter to recover a similar flow organisation ...
The effect of wall temperature on the transfer of kinetic energy in a hypersonic turbulent boundary ...
Supersonic compressible turbulent flow through a large size channel is studied numerically. The flow...
Submitted by Jairo Amaro (jairo.amaro@sibi.ufrj.br) on 2019-08-02T17:57:13Z No. of bitstreams: 1 1...
We study the structure of high-speed zero-pressure-gradient turbulent boundary layers up to friction...
We present a direct numerical simulation database of supersonic and hypersonic turbulent boundary la...
International audienceDirect numerical simulations (DNS) of supersonic turbulent boundary layers (ST...
In this paper, direct numerical simulation (DNS) is presented for spatially evolving turbulent bound...
This paper reports the direct numerical simulation (DNS) for hypersonic turbulent boundary layer ove...
Experimental results are presented for two turbulent boundary-layer experiments conducted at a free-...
The effects of surface roughness on compressible turbulent flow have not been studied as closely as ...
The compressibility effect and transport motion in highspeed turbulent boundary layer (TBL) is a fun...
International audienceThe present work is dedicated to the numerical study of statistical characteri...
We present spatially developing direct numerical simulations (DNS) of turbulent boundary layers at M...
We report the characteristics of wall shear stress (WSS) and wall heat flux (WHF) from direct numeri...
The flight conditions of a hypersonic vehicle on an ascent trajectory are computed and Reynolds-aver...
The effect of wall temperature on the transfer of kinetic energy in a hypersonic turbulent boundary ...
Supersonic compressible turbulent flow through a large size channel is studied numerically. The flow...
Submitted by Jairo Amaro (jairo.amaro@sibi.ufrj.br) on 2019-08-02T17:57:13Z No. of bitstreams: 1 1...
We study the structure of high-speed zero-pressure-gradient turbulent boundary layers up to friction...
We present a direct numerical simulation database of supersonic and hypersonic turbulent boundary la...
International audienceDirect numerical simulations (DNS) of supersonic turbulent boundary layers (ST...
In this paper, direct numerical simulation (DNS) is presented for spatially evolving turbulent bound...
This paper reports the direct numerical simulation (DNS) for hypersonic turbulent boundary layer ove...
Experimental results are presented for two turbulent boundary-layer experiments conducted at a free-...
The effects of surface roughness on compressible turbulent flow have not been studied as closely as ...
The compressibility effect and transport motion in highspeed turbulent boundary layer (TBL) is a fun...
International audienceThe present work is dedicated to the numerical study of statistical characteri...
We present spatially developing direct numerical simulations (DNS) of turbulent boundary layers at M...
We report the characteristics of wall shear stress (WSS) and wall heat flux (WHF) from direct numeri...
The flight conditions of a hypersonic vehicle on an ascent trajectory are computed and Reynolds-aver...
The effect of wall temperature on the transfer of kinetic energy in a hypersonic turbulent boundary ...
Supersonic compressible turbulent flow through a large size channel is studied numerically. The flow...
Submitted by Jairo Amaro (jairo.amaro@sibi.ufrj.br) on 2019-08-02T17:57:13Z No. of bitstreams: 1 1...