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Title: Direct simulation of turbulent swept flow over a wire in a channel.

Abstract

Turbulent swept flow over a cylindrical wire placed on a wall of a channel is investigated using direct numerical simulations. This geometry is a model of the flow through the wire-wrapped fuel pins, the heat exchanger, typical of many nuclear reactor designs. Mean flow along and across the wire axis is imposed, leading to the formation of separated flow regions. The Reynolds number based on the bulk velocity along the wire axis direction and the channel half height is 5400 and four cases are simulated with different flowrates across the wire. This configuration is topologically similar to backward-facing steps or slots with swept flow, except that the dominant flow is along the obstacle axis in the present study and the crossflow is smaller than the axial flow, i.e. the sweep angle is large. Mean velocities, turbulence statistics, wall shear stress and instantaneous flow structures are investigated. Particular attention is devoted to the statistics of the shear stress on the walls of the channel and the wire in the recirculation zone. The flow around the mean reattachment region, at the termination of the recirculating bubble, does not exhibit the typical decay of the mean shear stress observed in classical backward-facing stepmore » flows owing to the presence of a strong axial flow. The evolution of the mean wall shear stress angle after reattachment indicates that the flow recovers towards equilibrium at a rather slow rate, which decreases with sweep angle. Finally, the database is analysed to estimate resolution requirements, in particular around the recirculation zones, for large-eddy simulations. This has implications in more complete geometrical models of a wire-wrapped assembly, involving hundreds of fuel pins, where only turbulence modelling can be afforded computationally.« less

Authors:
; ;
Publication Date:
Research Org.:
Argonne National Lab. (ANL), Argonne, IL (United States)
Sponsoring Org.:
USDOE Office of Science (SC)
OSTI Identifier:
982686
Report Number(s):
ANL/MCS/JA-66702
Journal ID: 0022-1120; TRN: US201015%%1293
DOE Contract Number:  
DE-AC02-06CH11357
Resource Type:
Journal Article
Journal Name:
J. Fluid Mech.
Additional Journal Information:
Journal Volume: 651; Journal Issue: May 25, 2010
Country of Publication:
United States
Language:
ENGLISH
Subject:
36 MATERIALS SCIENCE; SIMULATION; WIRES; TURBULENT FLOW

Citation Formats

Ranjan, R, Pantano, C, Fischer, P, Mathematics and Computer Science, and Univ. of Illinois. Direct simulation of turbulent swept flow over a wire in a channel.. United States: N. p., 2010. Web. doi:10.1017/S0022112009993958.
Ranjan, R, Pantano, C, Fischer, P, Mathematics and Computer Science, & Univ. of Illinois. Direct simulation of turbulent swept flow over a wire in a channel.. United States. https://doi.org/10.1017/S0022112009993958
Ranjan, R, Pantano, C, Fischer, P, Mathematics and Computer Science, and Univ. of Illinois. 2010. "Direct simulation of turbulent swept flow over a wire in a channel.". United States. https://doi.org/10.1017/S0022112009993958.
@article{osti_982686,
title = {Direct simulation of turbulent swept flow over a wire in a channel.},
author = {Ranjan, R and Pantano, C and Fischer, P and Mathematics and Computer Science and Univ. of Illinois},
abstractNote = {Turbulent swept flow over a cylindrical wire placed on a wall of a channel is investigated using direct numerical simulations. This geometry is a model of the flow through the wire-wrapped fuel pins, the heat exchanger, typical of many nuclear reactor designs. Mean flow along and across the wire axis is imposed, leading to the formation of separated flow regions. The Reynolds number based on the bulk velocity along the wire axis direction and the channel half height is 5400 and four cases are simulated with different flowrates across the wire. This configuration is topologically similar to backward-facing steps or slots with swept flow, except that the dominant flow is along the obstacle axis in the present study and the crossflow is smaller than the axial flow, i.e. the sweep angle is large. Mean velocities, turbulence statistics, wall shear stress and instantaneous flow structures are investigated. Particular attention is devoted to the statistics of the shear stress on the walls of the channel and the wire in the recirculation zone. The flow around the mean reattachment region, at the termination of the recirculating bubble, does not exhibit the typical decay of the mean shear stress observed in classical backward-facing step flows owing to the presence of a strong axial flow. The evolution of the mean wall shear stress angle after reattachment indicates that the flow recovers towards equilibrium at a rather slow rate, which decreases with sweep angle. Finally, the database is analysed to estimate resolution requirements, in particular around the recirculation zones, for large-eddy simulations. This has implications in more complete geometrical models of a wire-wrapped assembly, involving hundreds of fuel pins, where only turbulence modelling can be afforded computationally.},
doi = {10.1017/S0022112009993958},
url = {https://www.osti.gov/biblio/982686}, journal = {J. Fluid Mech.},
number = May 25, 2010,
volume = 651,
place = {United States},
year = {Tue May 25 00:00:00 EDT 2010},
month = {Tue May 25 00:00:00 EDT 2010}
}