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http://dx.doi.org/10.12989/ose.2017.7.4.435

Prediction of the turning and zig-zag maneuvering performance of a surface combatant with URANS  

Duman, Suleyman (Department of Naval Architecture and Marine Engineering, Yildiz Technical University)
Bal, Sakir (Department of Naval Architecture and Marine Engineering, Istanbul Technical University)
Publication Information
Ocean Systems Engineering / v.7, no.4, 2017 , pp. 435-460 More about this Journal
Abstract
The main objective of this study is to investigate the turning and zig-zag maneuvering performance of the well-known naval surface combatant DTMB (David Taylor Model Basin) 5415 hull with URANS (Unsteady Reynolds-averaged Navier-Stokes) method. Numerical simulations of static drift tests have been performed by a commercial RANS solver based on a finite volume method (FVM) in an unsteady manner. The fluid flow is considered as 3-D, incompressible and fully turbulent. Hydrodynamic analyses have been carried out for a fixed Froude number 0.28. During the analyses, the free surface effects have been taken into account using VOF (Volume of Fluid) method and the hull is considered as fixed. First, the code has been validated with the available experimental data in literature. After validation, static drift, static rudder and drift and rudder tests have been simulated. The forces and moments acting on the hull have been computed with URANS approach. Numerical results have been applied to determine the hydrodynamic maneuvering coefficients, such as, velocity terms and rudder terms. The acceleration, angular velocity and cross-coupled terms have been taken from the available experimental data. A computer program has been developed to apply a fast maneuvering simulation technique. Abkowitz's non-linear mathematical model has been used to calculate the forces and moment acting on the hull during the maneuvering motion. Euler method on the other hand has been applied to solve the simultaneous differential equations. Turning and zig-zag maneuvering simulations have been carried out and the maneuvering characteristics have been determined and the numerical simulation results have been compared with the available data in literature. In addition, viscous effects have been investigated using Eulerian approach for several static drift cases.
Keywords
ship maneuvering; turning circle; zig-zag maneuver; CFD (Computational Fluid Dynamics); DTMB 5415; drift; wave deformations; hydrodynamic derivatives; viscous effects;
Citations & Related Records
Times Cited By KSCI : 2  (Citation Analysis)
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1 Abkowitz, M.A. (1964), Lectures on Ship Hydrodynamics - Steering and Maneuvering, Hy-5. Lyngby, Denmark: Hydro & Aerodynamic Laboratory.
2 Ankudinov, V. (1987), "Ship maneuvrability assessment in ship design", International Ship Manoeuvring Conference. London.
3 Bal, S. (2008), "Prediction of wave pattern and wave resistance of surface piercing bodies by a boundary element method", Int. J. Numer. Meth. Fl., 5(3), 305-329.
4 Bal, S. (2016), "Free surface effects on 2-D airfoils and 3-D wings moving over water", Ocean Syst. Eng., 6(3), 245-264.   DOI
5 Bhushan, S., Xing, T., Carrica, P. and Stern, F. (2007), "Model- and full-scale URANS/DES simulations for athena R/V resistance, powering, and motions", Numer. Ship Hydrodynam. Conference II, 122-142.
6 Celik, I., Ghia, U., Roache, P.J. and Christopher, J.F. (2008), "Procedure for estimation and reporting of uncertainty due to discretization in CFD applications", J. Fluid. Eng., 130(7), 1-4.
7 Clarke, D.B. and Gedling, P. (1982), "The application of manoeuvring criteria in hull design using linear theory", Transactions of the Institution of Naval Architects, RINA.
8 Duman, S. (2016), "Investigation of the turning performance of a surface combatant with URANS", Master's Thesis, Istanbul Technical University.
9 Duman, S. and Bal, S. (2016a), "Numerical investigation of viscous effects on the static PMM tests of ships", Proceedings of the 2nd International Meeting on Recent Advances in Prediction Techniques for Safe Manoeuvring of Ships and Submarines. Istanbul, Turkey.
10 Duman, S. and Bal, S. (2016b), "Numerical investigation of scale effects on maneuvering coefficients of DTMB 5415 hull", Proceedings of the 1st International Congress on Ship and Marine Technology, Piri Reis University, Tuzla, Istanbul, Turkey: The Chamber of Turkish Naval Architects and Marine Engineers.
11 Ferziger, J.H. and Peric, M. (2002), Computational Methods for Fluid Dynamics, (3 Ed.), Berlin: Springer.
12 Fossen, T.I. (1994), Guidance and Control of Ocean Vehicles, Chichester, New York: Wiley.
13 Inoue, S., Hirano, M. and Kijima, K. (1981), "Hydrodynamic derivatives on ship manoeuvring", Int. Shipbuild. Progress 28(321), 112-125.   DOI
14 Gertler, M. (1967), "The DTMB planar-motion-mechanism system", Test and Evaluation Report AD659053. Washington, DC: Naval Ship Research and Development Center.
15 Hajivand, A. and Mousavizadegan, S.H. (2015), "Virtual simulation of maneuvering captive tests for a surface vessel", Int. J. Naval Architect. Ocean Eng., 7(5), 848-872.   DOI
16 Hirt, C.W. and Nichols, B.D. (1981), "Volume of Fluid (VOF) method for the dynamics of free boundaries", J. Comput. Phys., 39(1), 201-225.   DOI
17 ITTC. (2011), "Practical guidelines for ship CFD applications", Proceedings of the 26th ITTC. In . Hague.
18 Kim, H., Akimoto, H. and Islam, H. (2015), "Estimation of the hydrodynamic derivatives by RANS simulation of planar motion mechanism test", Ocean Eng., 108, 129-139.   DOI
19 Kinaci, O.K., Sukas, O.F. and Bal, S. (2016), "Prediction of wave resistance by a reynolds-averaged navier-stokes equation-based computational fluid dynamics approach", Proceedings of the Institution of Mechanical Engineers, Part M: Journal of Engineering for the Maritime Environment, 230(3), 531-548.   DOI
20 Kim, W.J., Van, S.H. and Kim, D.H. (2001), "Measurement of flows around commercial ship models", Exp. Fluids, 31(5), 567-578.   DOI
21 Larsson, L., Stern, F. and Bertram, V. (2003), "Benchmarking of computational fluid dynamics for ship flows: The Gothenburg 2000 workshop", J. Ship Res., 47(1), 63-81.
22 Norrbin, N.H. (1971), "Theory and observations of on the use of a mathematical model for ship manoeuvring in deep and confined waters", SSPA, Gothenburg, Sweden 68.
23 Longo, J. and Stern, F. (2005), "Uncertainty assessment for towing tank tests with example for surface combatant DTMB model 5415", J. Ship Res., 49(1), 55-68.
24 Nikolaev, E. and Lebedeva, M. (1980), "On the nature of scale effects in manoeuvring tests with full-bodied ship models", Proceedings of the 13th Symposium on Naval Hydrodynamics, Tokyo, Japan.
25 "Nomenclature for Treating the Motion of a Submerged Body through a Fluid" (1952), Technical and Research Bulletin 1-5. SNAME.
26 Roache, P.J. (1994), "Perspective: A method for uniform reporting of grid refinement studies", J. Fluid. Eng., 116(3), 405.   DOI
27 Sakamoto, N. (2009), "URANS and DES simulations of static and dynamic maneuvering for surface combatant", PhD Thesis, University of Iowa.
28 SIMMAN. (2014), "Geometry and conditions of US navy combatant", simman2014.dk. http://simman2014.dk/ship-data/us-navy-combatant/geometry-and-conditions-us-navy-combatant/.
29 Simonsen, C.D., Otzen, J.F., Klimt, C., Larsen, N.L. and Stern F. (2012), "Maneuvering Predictions in the Early Design Phase Using CFD Generated PMM Data", Proceedings of the 29th Symposium on Naval Hydrodynamics, Gothenburg, Sweden.
30 Yoshimura, Y. (2005), "Mathematical model for manoeuvring ship motion (MMG Model)", Proceedings of the Workshop of Mathematical Models for Operations Involving Ship-Ship Interaction, Tokyo, Japan.
31 Simonsen, C.D. and Stern, F. (2003), "Verification and validation of RANS maneuvering simulation of Esso Osaka: Effects of drift and rudder angle on forces and moments", Comput. Fluids, 32(10), 1325-1356.   DOI
32 Smitt, W.L. (1970), "Steering and manoeuvring full-scale and model tests (Part 1)", Europian Shipbuild., 19 (6).
33 Stern, F., Wilson, R.V., Coleman, H.W. and Paterson, E.G. (2001), "Comprehensive approach to verification and validation of CFD simulations-Part 1: Methodology and procedures", J. Fluid. Eng. -T ASME, 123 (4), 793.   DOI
34 Tezdogan, T., Demirel, Y.K., Kellett, P., Khorasanchi, M., Incecik, A. and Turan, O. (2015), "Full-scale unsteady RANS CFD simulations of ship behaviour and performance in head seas due to slow steaming", Ocean Eng., 97, 186-206.   DOI
35 Uslu, Y. and Bal, S. (2008), "Numerical prediction of wave drag of 2-D and 3-D bodies under or on a free surface", Turkish J. Eng. Environ. Sci., 32, 177-188.
36 Toxopeus, S. and Lee, S.W. (2008), "Workshop on Verification and Validation of Ship Manoeuvring Simulation Methods", Proceedings of SIMMAN 2008 Workshop.
37 Yoon, H., Simonsen, C.D., Benedetti, L., Longo, J., Toda, Y. and Stern, F. (2015), "Benchmark CFD validation data for surface combatant 5415 in PMM maneuvers - Part I: force/moment/motion measurements", Ocean Eng., 109, 705-734.   DOI
38 Yoon, H. (2009), "Phase-averaged stereo-PIV flow field and force/ moment/motion measurements for surface combatant in PMM maneuvers", PhD Thesis, University of Iowa.