Blunt-body drag reduction through base cavity shape optimization

We present a numerical study on the drag reduction of a turbulent incompressible flow around two different blunt bodies, of height $H$ and length $L$, at a Reynolds number $Re=\rho U_{\infty} H/\mu=2000$, where $U_{\infty}$ is the turbulent incompressible free-stream velocity, $\rho$ is their density and $\mu$ their viscosity. The study is based on the optimization of the geometry of a cavity placed at the rear part of the body with the aim of increasing the base pressure. Thus, we have used an optimization algorithm, which implements the adjoint method, to compute the two-dimensional incompressible turbulent steady flow sensitivity field of axial forces on both bodies, and consequently modify the shape of the cavity to reduce the induced drag force. In addition, we have performed three dimensional numerical simulations using an IDDES model in order to analyze the drag reduction effect of the optimized cavities at higher Reynolds numbers.The results show average drag reductions of 17 and 25$\%$ for Re=2000, as well as more regularized and less chaotic wake flows in both bodies.