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Journal of Offshore Mechanics and Arctic Engineering | Volume 135 | Issue 1 | research-article
Research Papers: Offshore Technology

Second-Order Diffraction and Radiation of a Floating Body With Small Forward Speed

[+] Author and Article Information
Yan-Lin Shao

e-mail: shao.yanlin@ntnu.no

Odd M. Faltinsen

Centre for Ships and
Ocean Structures (CeSOS) and
Department of Marine Technology,
Norwegian University of Science and
Technology (NTNU),
N-7491, Trondheim, Norway

1Corresponding author.

Contributed by the Ocean Offshore and Arctic Engineering Division of ASME for publication in the JOURNAL OF OFFSHORE MECHANICS AND ARCTIC ENGINEERING. Manuscript received July 8, 2010; final manuscript received March 28, 2012; published online February 22, 2013. Assoc. Editor: Thomas Fu.

J. Offshore Mech. Arct. Eng 135(1), 011301 (Feb 22, 2013) (10 pages) Paper No: OMAE-10-1072; doi: 10.1115/1.4006929 History: Received July 08, 2010; Revised March 28, 2012
Article
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Citing Articles

The formulation of the second-order wave-current-body problem in the inertial coordinate system involves higher-order derivatives in the body boundary condition. A new method taking advantage of the body-fixed coordinate system in the near field is presented to avoid the calculation of higher-order derivatives in the body boundary condition. The new method has an advantage over the traditional method when the body surface has a sharp corner or high curvature. The nonlinear wave diffraction and forced oscillation of floating bodies are studied up to second order in wave slope. A small forward speed is taken into account. The results of the new method are compared with that of the traditional method based on a formulation in the inertial coordinate system. When the traditional method applies, good agreement has been obtained.
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References

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5
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7
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Isaacson, M., and Ng, J. Y. T., 1993, “Second-Order Wave Radiation of Three-Dimensional Bodies by Time-Domain Method,” Int. J. Offshore Polar Eng, ISOPE, 13(4), pp. 264–272.
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Teng, B., Bai, W., and Dong, G., 2002, “Simulation of Second-Order Radiation of 3D Bodies in Time Domain by a B-Spline Method,” Proceedings of the 12th International Offshore and Polar Engineering Conference, Vol. 12, pp. 487–493.
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Zhao, R., and Faltinsen, O. M., 1990, “Interaction Between Current, Waves and Marine Structures,” 5th International Conference on Numerical Ship Hydrodynamics, Hiroshima, National Academy Press, Washington, D.C., pp. 513–528.
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Skourup, J., Cheung, K. F., Bingham, H. B., and Büchmann, B., 2000, “Loads on a 3D Body Due to Second-Order Waves and a Current,” Ocean Eng., 27(7), pp. 707–727. [CrossRef]
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Inglis, R. B., and Price, W. G., 1981, “The Influence of Speed Dependent Boundary Condition in Three-Dimensional Ship Motion Problems,” Int. Shipbuilding Progress, 28(318), pp. 22–29.
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Iwashita, H., and Ohkusu, M., 1989, “Hydrodynamic Forces on a Ship Moving at Forward Speed in Waves,” J. Soc. Naval Architects Jpn., 166, pp. 187–205. [CrossRef]
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Iwashita, H., and Ito, A., 1998, “Seakeeping Computations of a Blunt Ship Capturing the Influence of the Steady Flow,” Ship Technol. Res., 45(4), pp. 159–171.
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Chen, X. B., Diebold, L., and DoutreleauY., 2000, “New Green Function Method to Predict Wave-Induced Ship Motions and Loads,” Proceedings of the 23rd Symposium on Naval Hydrodynamics, Val de Reuil, France, pp. 18–33.
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Duan, W. Y., and Price, W. G., 2002, “A Numerical Method to Solve the mj-Terms of a Submerged Body With Forward Speed,” Int. J. Numer. Methods Fluids, 40, pp. 655–667. [CrossRef]
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Kim, B., 2005, “Some Considerations on Forward-Speed Seakeeping Calculations in Frequency Domain,” Int. J. Offshore Polar Eng., 15, pp. 189–197.
21
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22
Zhao, R., and Faltinsen, O. M., 1989, “A Discussion of the m-Terms in the Wave-Body Interaction Problem,” International Workshop on Water Waves and Floating Bodies, Oystese, Norway, May 7–10.
23
Wu, G. X., 1991, “A Numerical Scheme for Calculating the mj-Terms in Wave-Current-Body Interaction Problem,” Appl. Ocean Res., 13(6), pp. 317–319. [CrossRef]
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Chen, X. B., and Malenica, S., 1998, “Interaction Effects of Local Steady Flow on Wave Diffraction-Radiation at Low Forward Speed,” Int. J. Offshore Polar Eng., 8(2), pp. 102–109.
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Bingham, H. B., and Maniar, H. D., 1996, “Computing the Double-Body m-Terms Using a B-Spline Based Panel Method,” International Workshop on Water Waves and Floating Bodies, Hamburg, Germany, Mar. 17–20.
26
Shao, Y. L., and Faltinsen, O. M., 2010, “Use of Body-Fixed Coordinate System in Analysis of Weakly-Nonlinear Wave-Body Problems,” Appl. Ocean Res., 32(1), pp. 20–33. [CrossRef]
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Faltinsen, O. M., 1993, Sea Loads on Ships and Offshore Structures, Cambridge University Press, Cambridge.
28
Faltinsen, O. M., 2005, Hydrodynamics of High-Speed Marine Vehicles, Cambridge University Press, Cambridge.
29
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Faltinsen, O. M., and Timokha, A. N., 2009, Sloshing, Cambridge University Press, Cambridge.
31
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34
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36
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37
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38
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39
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40
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BertramV., 2000, Practical Ship Hydrodynamics, Butterworth-Heinemann, London.

Figures

Grahic Jump Location
Fig. 1

Definition of coordinate systems and the illustration of water domain, body boundary, free surfaces, control surface, bottom surface, and damping zone

+Definition of coordinate systems and the illustration of water domain, body boundary, free surfaces, control surface, bottom surface, and damping zone
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Definition of coordinate systems and the illustration of water domain, body boundary, free surfaces, control surface, bottom surface, and damping zone
Grahic Jump Location
Fig. 2

An example of the meshes on SB, SF1, and SC of the inner domain

+An example of the meshes on SB, SF1, and SC of the inner domain
View Large  |  Save Figure  |  Download Slide (.ppt)
An example of the meshes on SB, SF1, and SC of the inner domain
Grahic Jump Location
Fig. 3

An example of meshes on the free surfaces SF1 and SF20

+An example of meshes on the free surfaces SF1 and SF20
View Large  |  Save Figure  |  Download Slide (.ppt)
An example of meshes on the free surfaces SF1 and SF20
Grahic Jump Location
Fig. 4

The amplitude of the nondimensional first-order inline force on a vertical bottom mounted circular cylinder versus kR. A is the wave amplitude. h = R, Fr = 0.1.

+The amplitude of the nondimensional first-order inline force on a vertical bottom mounted circular cylinder versus kR. A is the wave amplitude. h = R, Fr = 0.1.
View Large  |  Save Figure  |  Download Slide (.ppt)
The amplitude of the nondimensional first-order inline force on a vertical bottom mounted circular cylinder versus kR. A is the wave amplitude. h = R, Fr = 0.1.
Grahic Jump Location
Fig. 5

The amplitude of the nondimensional first-order inline force on a vertical bottom mounted circular cylinder versus kR. A is the wave amplitude. h = R, Fr =  − 0.1.

+The amplitude of the nondimensional first-order inline force on a vertical bottom mounted circular cylinder versus kR. A is the wave amplitude. h = R, Fr =  − 0.1.
View Large  |  Save Figure  |  Download Slide (.ppt)
The amplitude of the nondimensional first-order inline force on a vertical bottom mounted circular cylinder versus kR. A is the wave amplitude. h = R, Fr =  − 0.1.
Grahic Jump Location
Fig. 6

Nondimensional mean drift force on a vertical bottom mounted circular cylinder versus kR. A is the wave amplitude. h = R, Fr =  − 0.1.

+Nondimensional mean drift force on a vertical bottom mounted circular cylinder versus kR. A is the wave amplitude. h = R, Fr =  − 0.1.
View Large  |  Save Figure  |  Download Slide (.ppt)
Nondimensional mean drift force on a vertical bottom mounted circular cylinder versus kR. A is the wave amplitude. h = R, Fr =  − 0.1.
Grahic Jump Location
Fig. 7

The amplitude of nondimensional sum-frequency inline force on a vertical bottom mounted circular cylinder versus kR. h = R.

+The amplitude of nondimensional sum-frequency inline force on a vertical bottom mounted circular cylinder versus kR. h = R.
View Large  |  Save Figure  |  Download Slide (.ppt)
The amplitude of nondimensional sum-frequency inline force on a vertical bottom mounted circular cylinder versus kR. h = R.
Grahic Jump Location
Fig. 8

The nondimensional surge added mass for a vertical circular cylinder compared with the analytical results by Malenica et al. [39]. The draft is equal to the water depth h and the radius R. Fr = 0.0.

+The nondimensional surge added mass for a vertical circular cylinder compared with the analytical results by Malenica et al. [39]. The draft is equal to the water depth h and the radius R. Fr = 0.0.
View Large  |  Save Figure  |  Download Slide (.ppt)
The nondimensional surge added mass for a vertical circular cylinder compared with the analytical results by Malenica et al. [39]. The draft is equal to the water depth h and the radius R. Fr = 0.0.
Grahic Jump Location
Fig. 9

The nondimensional surge damping coefficient for a vertical circular cylinder compared with the analytical results by Malenica et al. [39]. The draft is equal to the water depth h and the radius R. Fr = 0.0.

+The nondimensional surge damping coefficient for a vertical circular cylinder compared with the analytical results by Malenica et al. [39]. The draft is equal to the water depth h and the radius R. Fr = 0.0.
View Large  |  Save Figure  |  Download Slide (.ppt)
The nondimensional surge damping coefficient for a vertical circular cylinder compared with the analytical results by Malenica et al. [39]. The draft is equal to the water depth h and the radius R. Fr = 0.0.
Grahic Jump Location
Fig. 10

The nondimensional surge added mass for a vertical circular cylinder compared with the analytical results by Malenica et al. [39]. The draft is equal to the water depth h and the radius R. Fr =  − 0.05.

+The nondimensional surge added mass for a vertical circular cylinder compared with the analytical results by Malenica et al. [39]. The draft is equal to the water depth h and the radius R. Fr =  − 0.05.
View Large  |  Save Figure  |  Download Slide (.ppt)
The nondimensional surge added mass for a vertical circular cylinder compared with the analytical results by Malenica et al. [39]. The draft is equal to the water depth h and the radius R. Fr =  − 0.05.
Grahic Jump Location
Fig. 11

The nondimensional surge damping coefficient for a vertical circular cylinder compared with the analytical results by Malenica et al. [39]. The draft is equal to the water depth h and the radius R. Fr =  − 0.05.

+The nondimensional surge damping coefficient for a vertical circular cylinder compared with the analytical results by Malenica et al. [39]. The draft is equal to the water depth h and the radius R. Fr =  − 0.05.
View Large  |  Save Figure  |  Download Slide (.ppt)
The nondimensional surge damping coefficient for a vertical circular cylinder compared with the analytical results by Malenica et al. [39]. The draft is equal to the water depth h and the radius R. Fr =  − 0.05.
Grahic Jump Location
Fig. 12

The mean drift force and the amplitude of the sum-frequency force on a vertical circular cylinder versus kR. The draft is equal to the water depth h and the radius R. Fr = 0.05. The surge amplitude is 0.05R.

+The mean drift force and the amplitude of the sum-frequency force on a vertical circular cylinder versus kR. The draft is equal to the water depth h and the radius R. Fr = 0.05. The surge amplitude is 0.05R.
View Large  |  Save Figure  |  Download Slide (.ppt)
The mean drift force and the amplitude of the sum-frequency force on a vertical circular cylinder versus kR. The draft is equal to the water depth h and the radius R. Fr = 0.05. The surge amplitude is 0.05R.
Grahic Jump Location
Fig. 13

Sketch of a section of the axisymmetric body in the oxz plane

+Sketch of a section of the axisymmetric body in the oxz plane
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Sketch of a section of the axisymmetric body in the oxz plane
Grahic Jump Location
Fig. 14

Time history of the first-order wave force in the x direction on the axisymmetric body defined in Fig. 13 under forced pitching about COG. Fr = U/gR = 0.05, kR = 1.2.

+Time history of the first-order wave force in the x direction on the axisymmetric body defined in Fig. 13 under forced pitching about COG. Fr = U/gR = 0.05, kR = 1.2.
View Large  |  Save Figure  |  Download Slide (.ppt)
Time history of the first-order wave force in the x direction on the axisymmetric body defined in Fig. 13 under forced pitching about COG. Fr = U/gR = 0.05, kR = 1.2.
Grahic Jump Location
Fig. 15

Time history of the first-order wave force in the z direction on the axisymmetric body defined in Fig. 13 under forced pitching about COG. Fr = U/gR = 0.05, kR = 1.2.

+Time history of the first-order wave force in the z direction on the axisymmetric body defined in Fig. 13 under forced pitching about COG. Fr = U/gR = 0.05, kR = 1.2.
View Large  |  Save Figure  |  Download Slide (.ppt)
Time history of the first-order wave force in the z direction on the axisymmetric body defined in Fig. 13 under forced pitching about COG. Fr = U/gR = 0.05, kR = 1.2.
Grahic Jump Location
Fig. 16

Time history of the first-order pitch moment about an axis through COG for the axisymmetric body defined in Fig. 13 under forced pitching about COG. Fr = U/gR = 0.05, kR = 1.2.

+Time history of the first-order pitch moment about an axis through COG for the axisymmetric body defined in Fig. 13 under forced pitching about COG. Fr = U/gR = 0.05, kR = 1.2.
View Large  |  Save Figure  |  Download Slide (.ppt)
Time history of the first-order pitch moment about an axis through COG for the axisymmetric body defined in Fig. 13 under forced pitching about COG. Fr = U/gR = 0.05, kR = 1.2.
Grahic Jump Location
Fig. 17

Time history of the second-order wave force in the z direction on the axisymmetric body defined in Fig. 13 under forced pitching about COG. Fr = U/gR = 0.05, kR = 1.2.

+Time history of the second-order wave force in the z direction on the axisymmetric body defined in Fig. 13 under forced pitching about COG. Fr = U/gR = 0.05, kR = 1.2.
View Large  |  Save Figure  |  Download Slide (.ppt)
Time history of the second-order wave force in the z direction on the axisymmetric body defined in Fig. 13 under forced pitching about COG. Fr = U/gR = 0.05, kR = 1.2.
Grahic Jump Location
Fig. 18

Amplitude of the sum-frequency force in the z direction versus kR for an axisymmetric body defined in Fig. 13 under forced pitch motion about COG. Fr = 0.05.

+Amplitude of the sum-frequency force in the z direction versus kR for an axisymmetric body defined in Fig. 13 under forced pitch motion about COG. Fr = 0.05.
View Large  |  Save Figure  |  Download Slide (.ppt)
Amplitude of the sum-frequency force in the z direction versus kR for an axisymmetric body defined in Fig. 13 under forced pitch motion about COG. Fr = 0.05.

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