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Abstract
Accurate hydrodynamic calculations for semi-submersibles are critical to support modern rapid exploration and extraction of ocean resources. In order to speed hydrodynamic calculations, lines modeling structures were separated into structural parts and then fitted to Non-uniform Rational B-spline (NURBS). In this way, the bow and stern section lines were generated. Modeling of the intersections of the parts was then done with the universal modeling tool MSC.Patran. Mesh was gererated on the model in order to obtain points of intersection on the joints, and then these points were fitted to NURBS. Next, the patch representation method was adopted to generate the meshes of wetted surfaces and interior free surfaces. Velocity potentials on the surfaces were calculated separately, on basis of which the irregular frequency effect was dealt with in the calculation of hydrodynamic coefficients. Finally, the motion response of the semi-submersible was calculated, and in order to improve calculations of vertical motion, a damping term was affixed in the vertical direction. The results show that the above methods can generate fine mesh accurately representing the wetted surface of a semi-submersible and thus improve the accuracy of hydrodynamic calculations.
Keywords
splines
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surface fitting
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semi-submersible
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irregular frequency
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Hui-long Ren, Wen-xi Liu.
Calculation of hydrodynamics for semi-submersibles based on NURBS.
Journal of Marine Science and Application, 2008, 7(2): 91-97 DOI:10.1007/s11804-008-7083-z
| [1] |
Rogers D. F., Satterfield S. G. B-Spline surface for ship hull design[J]. Computer Graphics, 1980, 14(3): 211-217
|
| [2] |
Shi F. Computer-aided design and non-uniform rational B-spline[M]. 2001, Beijing: Higher Education Press, 211-304
|
| [3] |
Sun J., Yang C. Computer graphics[M]. 1995, Beijing: Tsinghua University Press, 105-289
|
| [4] |
Zhao Z. Reconstruction of surface on NURBS[D]. 2003, Beijing: Tsinghua University, 50-107
|
| [5] |
Zhang J. Research on generating subdivision surface and applying to surface modeling[D]. 2003, Hangzhou: Zhejiang University, 20-100
|
| [6] |
Wu D. Ship surface representation and 3D ship design[D]. 2002, Dalian: Dalian University of Technology, 23-104
|
| [7] |
Lin Y., Ji Z. Mathematical description and computer method for B-spline hull surface[J]. Shipbuilding of China, 1996, 11(4): 20-24
|
| [8] |
Chen S., Chen B. Hull line design for twin stern ship based on NURBS curve[J]. Shipbuilding of China, 2001, 42(2): 7-11
|
| [9] |
Li Y., Liu Y., Miao G. Potential flow solution using higher-order boundary element method with rankine source[J]. Journal of Hydrodynamics, 1999, 14(1): 80-89
|
| [10] |
Bai W. Non-linear wave interaction with arbitrary 3-D bodies[D]. 2001, Dalian: Dalian University of Technology, 10-88
|
| [11] |
Qian K. Study on calculation of motions and loads on floating bodies in large amplitude waves[D]. 2004, Dalian: Dalian University of Technology, 11-67
|
| [12] |
Zhang X. Numerical calculation for hydrodynamics of 3-Dship hull based on B-spline[D]. 2004, Wuhan: Wuhan University of Technology, 31-45
|
| [13] |
Liu W., Ren H. Reconstruction technology of complex ship surface based on NURBS[J]. Journal of Harbin Engineering University, 2007, 28(11): 603-609
|
| [14] |
Lamb H. Hydrodynamics[M]. 1932, London: Cambridge University Press, 200-356
|
| [15] |
Lee S. Removing the irrenular frequencies from interval equations in wave-body interactions[J]. J fluid Mech, 1989, 20(7): 393-418
|
| [16] |
Teng B., Li Y. A unique solvable higher order BEM for wave diffraction and radiation[J]. China Ocean Engineering, 1996, 10(3): 333-342
|
| [17] |
Duan W., He W. A boundary element method for removing the irregular frequency effect in solving the hydrodynamic coefficients[J]. Journal of Hydrodynamics, 2002, 17(2): 156-161
|
| [18] |
Sun L., Teng B. Dicontinuous higher boundary element method for removing of irregular frequencies[J]. The Ocean Engineering, 2004, 22(4): 51-59
|
