A three-dimensional model of a two-part underwater towed system is studied. In the model, the governing equations of cables are established based on the Ablow and Schechter method. The boundary conditions for the two-part underwater towed system are derived. The six-degrees-of-freedom equations of motion for submarine simulations are adopted to predict the hydrodynamic performance of a towed vehicle. The established governing equations for the system are then solved using a central finite difference method. In this paper several algorithms are used to solve this special form of finite difference equations. The results in this paper indicate that the two-part underwater towed system improves the dynamic behavior of the towed vehicle and is an easy way to decouple the towing ship motion from the towed vehicle. Because the model uses an implicit time integration, it is stable for large time steps and is an effective algorithm for simulation of a large-scale underwater towed system.
[1]
D. A. Chapman,et al.
Towed cable behaviour during ship turning manoeuvers
,
1984
.
[2]
G. E. Hearn,et al.
The Influence of Practical Time Integration Schemes on Dynamic Mooring Line Analysis
,
1991
.
[3]
Christopher T. Howell,et al.
NUMERICAL ANALYSIS OF 2-D NONLINEAR CABLE EQUATIONS WITH APPLICATIONS TO LOW-TENSION PROBLEMS
,
1991
.
[4]
C. M. Ablow,et al.
Numerical simulation of undersea cable dynamics
,
1983
.
[5]
T. Walton,et al.
Calculation of transient motion of submerged cables
,
1960
.
[6]
Morton Gertler,et al.
STANDARD EQUATIONS OF MOTION FOR SUBMARINE SIMULATION
,
1967
.
[7]
Sd Ranmuthugala,et al.
Dynamic Simulation of a Two-Part Underwater Tow
,
1993
.
[8]
J. J. Burgess.
Modelling Of Undersea Cable Installation With A Finite Difference Method
,
1991
.