Direct numerical simulation of convective heat transfer of supercritical pressure in a vertical tube with buoyancy and thermal acceleration effects
DOI10.1017/JFM.2021.705zbMath1494.76047OpenAlexW3202450083MaRDI QIDQ5157302
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Publication date: 13 October 2021
Published in: Journal of Fluid Mechanics (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1017/jfm.2021.705
heat transfersecond-order central difference schemeturbulent convectionbuoyancy-driven instabilityorthogonal decomposition methodthird-order Runge-Kutta schemestretch-to-disrupt mechanism
Finite difference methods applied to problems in fluid mechanics (76M20) Direct numerical and large eddy simulation of turbulence (76F65) Convective turbulence (76F35) Diffusive and convective heat and mass transfer, heat flow (80A19)
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Cites Work
- Assessment of performance of turbulence models in predicting supercritical pressure heat transfer in a vertical tube
- A simple boundary condition for unbounded hyperbolic flows
- Assessment by comparison with DNS data of turbulence models used in simulations of mixed convection
- Direct numerical simulation of turbulent supercritical flows with heat transfer
- The Turbulent Flows of Supercritical Fluids with Heat Transfer
- Turbulence attenuation in simultaneously heated and cooled annular flows at supercritical pressure
- Laminarisation of flow at low Reynolds number due to streamwise body force
- Turbulence in transient channel flow
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