Abstract
Computational fluid dynamics, CFD, is becoming an essential tool in the prediction of the hydrodynamic efforts and flow characteristics of underwater vehicles for manoeuvring studies. However, when applied to the manoeuvrability of autonomous underwater vehicles, AUVs, most studies have focused on the determination of static coefficients without considering the effects of the vehicle control surface deflection. This paper analyses the hydrodynamic efforts generated on an AUV considering the combined effects of the control surface deflection and the angle of attack using CFD software based on the Reynolds-averaged Navier-Stokes formulations. The CFD simulations are also independently conducted for the AUV bare hull and control surface to better identify their individual and interference efforts and to validate the simulations by comparing the experimental results obtained in a towing tank. Several simulations of the bare hull case were conducted to select the k-. ω SST turbulent model with the viscosity approach that best predicts its hydrodynamic efforts. Mesh sensitivity analyses were conducted for all simulations. For the flow around the control surfaces, the CFD results were analysed according to two different methodologies, standard and nonlinear. The nonlinear regression methodology provides better results than the standard methodology does for predicting the stall at the control surface. The flow simulations have shown that the occurrence of the control surface stall depends on a linear relationship between the angle of attack and the control surface deflection. This type of information can be used in designing the vehicle's autopilot system.
Original language | English |
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Pages (from-to) | 168-181 |
Number of pages | 14 |
Journal | Applied Ocean Research |
Volume | 42 |
Early online date | 2 Jul 2013 |
DOIs | |
Publication status | Published - 31 Aug 2013 |
Keywords
- AUV
- CFD
- hydrodynamic forces
- mesh sensitivity analysis
- validation and verification
- computational fluid dynamic (CFD)
- verification and validation (V&V)
- hydrodynamic
- autonomous underwater vehicle (AUV)
- rudders
- hydrodynamic coefficients
- turbulence models
- flow topology
- non-linear analysis
- marine robotics