Title :
An accurate four-quadrant nonlinear dynamical model for marine thrusters: theory and experimental validation
Author :
Bachmayer, Ralf ; Whitcomb, Louis L. ; Grosenbaugh, Mark A.
Author_Institution :
Dept. of Mech. Eng., Johns Hopkins Univ., Baltimore, MD, USA
Abstract :
This paper reports two specific improvements in the finite-dimensional nonlinear dynamical modeling of marine thrusters. Previously reported four-quadrant models have employed thin airfoil theory considering only axial fluid flow and using sinusoidal lift/drag curves. First, we present a thruster model incorporating the effects of rotational fluid velocity and inertia on thruster response. Second, we report a novel method for experimentally determining nonsinusoidal lift/drag curves. The model parameters are identified using experimental thruster data (force, torque, and fluid velocity). The models are evaluated by comparing experimental performance data with numerical model simulations. The data indicates that thruster models incorporating both reported enhancements provide superior accuracy in both transient and steady-state responses.
Keywords :
drag; flow simulation; force control; marine vehicles; modelling; nonlinear dynamical systems; position control; propulsion; transient response; axial flow model; dynamic positioning; dynamic response; finite-dimensional nonlinear dynamical modeling; four-quadrant nonlinear dynamical model; inertia effect; marine propulsion; marine thrusters; marine vehicle control; nonsinusoidal lift/drag curves; rotational fluid velocity effect; steady-state response; thrust control; thruster response; torque; transient response; Acoustic measurements; Drag; Fluid dynamics; Fluid flow; Hydrodynamics; Nonlinear dynamical systems; Position measurement; Predictive models; Propellers; Vehicle dynamics;
Journal_Title :
Oceanic Engineering, IEEE Journal of
