Numerical investigation of the air-side performance of louver fin-and-tube radiators having rectangular, tapered and airfoil section configuration

“…Factors were found independent of fin pitch and decreased with the increase in tube pitch. The air side performance of tapered, airfoil, and rectangular LFCHE was numerically studied, with different louver angles and lengths [ 32 ]. The highest Nusselt number and minimum friction factor were achieved with the airfoil design, particularly at a louver angle of 23 .…”

Numerical investigation of louver edges effect on the performances of louvered fin compact heat exchanger

“…Factors were found independent of fin pitch and decreased with the increase in tube pitch. The air side performance of tapered, airfoil, and rectangular LFCHE was numerically studied, with different louver angles and lengths [ 32 ]. The highest Nusselt number and minimum friction factor were achieved with the airfoil design, particularly at a louver angle of 23 .…”

Numerical investigation of louver edges effect on the performances of louvered fin compact heat exchanger

Thermo-hydraulic performance evaluation of a NACA 63-015 heat exchanger with shark denticles as surface textures

Numerical Study of the Influence of Base Tube Shape on Fin-and-Tube Heat Exchangers