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ISSN 打印: 1064-2285

ISSN 在线: 2162-6561

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COMPUTATIONAL THERMAL ANALYSIS OF TURBULENT FORCED-CONVECTION FLOW IN AN AIR CHANNEL WITH A FLAT RECTANGULAR FIN AND DOWNSTREAM V-SHAPED BAFFLE

卷 50, 册 18, 2019, pp. 1781-1818
DOI: 10.1615/HeatTransRes.2019026143
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摘要

Turbulent forced-convection fluid dynamic simulations were conducted to investigate the impacts of different baffle shapes on the thermal aerodynamic performance of a horizontal two-dimensional channel of rectangular section with wall-mounted baffles and fins. The top wall was put in a constant temperature condition, as the bottom wall was thermally insulated. Two obstacles, having different shapes, i.e., simple and 45° downstream V-shaped, were inserted into the channel and fixed to the upper and lower walls, in a periodically staggered manner. The fluid flow model was governed by the RANS equations and the energy equation. All these equations were discretized by the FVM, handled the pressure-velocity coupling with the SIMPLE discretization algorithm and solved using a CFD technique. This represents a very important issue in the area of shell-and-tube heat exchangers where the flow must be characterized; there is also a need to identify the velocity distribution, as well as the existence and the extension of possible recirculations.

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