Simulations of the DARPA Suboff submarine including self-propulsion with the E1619 propeller

Recommended Citation Chase, Nathan. "Simulations of the DARPA Suboff submarine including self-propulsion with the E1619 propeller. ii ACKNOWLEDGEMENTS I would like to thank my advisor, Dr. Pablo Carrica. His guidance and encouragement throughout my graduate career has been instrumental. I would also like to thank my other committee members, Dr. Fred Stern and Dr. Ching-Long Lin, for taking time out of their schedules to assist me in this process. I would like to also acknowledge the help I have received from other students at IIHR-Hydroscience and Engineering and the financial support from the Office of Naval Research under Grant N000141110232, with Dr. Ki-Han Kim as the program manager. iii ABSTRACT Simulations of the DARPA Suboff submarine and the submarine propeller E1619 using the overset flow solver CFDShip-Iowa V4.5 are presented. The hull was tested in a straight ahead simulation and also in a starboard turn. Propeller open water curves were obtained for two grids for a wide range of advance coefficients covering high to moderately low loads, and results compared with available experimental data. A verification study was performed for one advance coefficient () on four grids and three time step sizes. The effect of the turbulence model on the wake was evaluated at comparing results with RANS, DES, DDES, and with no turbulence model showing that RANS overly dissipates the wake and that in the solution with no turbulence model the tip vortices quickly become unphysically unstable. Tip vortex pairing is observed and described for revealing multiple vortices merging for higher loads. The wake velocities are compared against experimental data for showing good agreement. Self-propulsion computations of the DARPA Suboff generic submarine hull fitted with sail, rudders, stern planes, and the E1619 propeller were performed in model scale and the resulting propeller performance analyzed.