Hydrodynamic Analysis of NACA 4415 Hydrofoil For Marine Applications
DOI:
https://doi.org/10.18311/jmmf/2023/36040Keywords:
CFD, Flow Separation, Hydrofoil, Kort-Nozzle, Marine Application, NACA4415Abstract
In the present research, Computational Fluid Dynamics (CFD) analysis has been conducted to investigate the practical utility of ducted design for marine propellers for a range of Reynolds numbers (Re). Hydrodynamic characteristics are investigated for ducted propeller –Kort nozzle for various duct angles (0o ≤ α ≤ 10o). The Kort nozzle duct section is less explored with NACA hydrofoils and has been a hot research topic in the domain. Here, the hydrodynamic characteristics of the duct section are numerically investigated, considering NACA4415 foil. All the simulations are performed using ANSYS-FLUENT in a range of 1×106 < Re < 5×106. We have used the k −ω SST turbulence model during our investigation. The performance of NACA4415 is evaluated concerning the lift, drag, and pressure coefficient for various angles of attack (−12o < α < 12o). These models were
employed for nozzle configuration at different shroud/duct angles( 0◦<α d <10◦).It is found that the ducted configuration for the considered hydrofoil performs the best with a duct angle 4o < α d < 6 o with respect to hydrodynamic characteristics.
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