Nonlinear Computation of Ship Motions in the Time-Domain Using 2D+t Theory

Motions of high-speed displacement ships in waves have been predicted based on a body-exact strip-theory method in the time domain (2D+t). Nonlinear body boundary conditions were applied on instantaneous wetted surfaces. Linear boundary conditions were used on the free surface so that the 2D transient free surface Green function can be employed. Interactions among the strips of the ship hull were considered. A far field method was adopted to compute the hydrodynamic forces. Validation studies have been carried out for two Wigley hull ships in regular waves. Numerical results were compared with experimental data and those by other numerical methods.

Volume 6: Nick Newman Symposium on Marine Hydrodynamics; Yoshida and Maeda Special Symposium on Ocean Space Utilization; Special Symposium on Offshore Renewable Energy ◽

Nonlinear Ship Motions in the Time-Domain Using a Body-Exact Strip Theory

10.1115/omae2008-57069 ◽

2008 ◽

Cited By ~ 3

Author(s):

Piotr J. Bandyk ◽

Robert F. Beck

Keyword(s):

Free Surface ◽

Boundary Conditions ◽

Time Domain ◽

The Body ◽

Ship Motions ◽

Surface Boundary ◽

Theory Approach ◽

Offshore Structure ◽

Time Step ◽

Strip Theory

Modern offshore structure and ship design requires an understanding of responses in large seas. A nonlinear time-domain method may be used to perform computational analyses of these events. To be useful in preliminary design, the method must be computationally efficient and accurate. This paper presents a body-exact strip theory approach to compute wave-body interactions for large amplitude ship motions. The exact body boundary conditions and linearized free surface boundary conditions are used. At each time step, the body surface and free surface are regrided due to the changing wetted body geometry. Numerical and real hull forms are used in the computations. Validation and comparisons of hydrodynamic forces are presented. Selected results are shown illustrating the robustness and capabilities of the body-exact strip theory. Finally, an equation of motion solver is implemented to predict the motions of the vessel in a seaway.

Ship Motion Computations Using a High Froude Number Time Domain Strip Theory

10.5957/jsr.2006.50.1.15 ◽

2006 ◽

Vol 50 (01) ◽

pp. 15-30

Author(s):

D. S. Holloway ◽

M. R. Davis

Keyword(s):

Froude Number ◽

Time Domain ◽

High Speed ◽

Equations Of Motion ◽

Fluid Motion ◽

Three Dimensional ◽

Viscous Effects ◽

Strip Theory ◽

Large Amplitude Motions ◽

High-speed strip theories are discussed, and a time domain formulation making use of a fixed reference frame for the two-dimensional fluid motion is described in detail. This, and classical (low-speed) strip theory, are compared with the experimental results of Wellicome et al. (1995) up to a Froude number of 0.8, as well as with our own test data for a semi-SWATH, demonstrating the marked improvement of the predictions of the former at high speeds, while the need to account for modest viscous effects at these speeds is also argued. A significant contribution to time domain computations is a method of stabilizing the integration of the ship's equations of motion, which are inherently unstable due to feedback from implicit added mass components of the hydrodynamic force. The time domain high-speed theory is recommended as a practical alternative to three-dimensional methods. It also facilitates the investigation of large-amplitude motions with stern or bow emergence and forms a simulation base for the investigation of ride control systems and local or global loads.

NON LINEAR ANALYSIS OF SHIP MOTIONS AND LOADS IN LARGE AMPLITUDE WAVES

The International Journal of Maritime Engineering ◽

10.5750/ijme.v153ia2.850 ◽

2021 ◽

Vol 153 (A2) ◽

Author(s):

G Mortola ◽

A Incecik ◽

O Turan ◽

S.E. Hirdaris

Keyword(s):

Frequency Domain ◽

Time Domain ◽

Large Amplitude ◽

Linear Time ◽

Ship Motions ◽

Wave Loads ◽

Time Step ◽

Strip Theory ◽

Non Linear ◽

A non linear time domain formulation for ship motions and wave loads is presented and applied to the S175 containership. The paper describes the mathematical formulations and assumptions, with particular attention to the calculation of the hydrodynamic force in the time domain. In this formulation all the forces involved are non linear and time dependent. Hydrodynamic forces are calculated in the frequency domain and related to the time domain solution for each time step. Restoring and exciting forces are evaluated directly in time domain in a way of the hull wetted surface. The results are compared with linear strip theory and linear three dimensional Green function frequency domain seakeeping methodologies with the intent of validation. The comparison shows a satisfactory agreement in the range of small amplitude motions. A first approach to large amplitude motion analysis displays the importance of incorporating the non linear behaviour of motions and loads in the solution of the seakeeping problem.

Operation of T-Foils and Stern Tabs to Improve Passenger Comfort on High-Speed Ferries

10.5957/josr.07200047 ◽

2021 ◽

pp. 1-20

Author(s):

Michael R. Davis

Keyword(s):

Time Domain ◽

High Speed ◽

Transfer Functions ◽

Passenger Comfort ◽

Strip Theory ◽

Head Waves ◽

Similar Range ◽

Vertical Accelerations ◽

The Time Domain ◽

Passenger Discomfort

High-speed ferries of around 100 m length cruising at around 40 knots can cause significant passenger discomfort in head waves. This is due to the frequencies of encountering waves, of maximum hull response to encountered waves and of maximum passenger discomfort all falling within a similar range. In this paper, the benefit obtained by fitting active T-foils and stern tabs to control heave and pitch in head waves is considered. Ship motion responses are computed by numerical integration in the time domain including unsteady control actions using a time domain, high-speed strip theory. This obviates the need to identify transfer functions, the computed time responses including nonlinear hull immersion terms. The largest passenger vertical accelerations occur at forward locations and are best controlled by a forward located T-foil acting in combination with active stern tabs. Various feedback control algorithms have been considered and it is found that pitch damping control gives the greatest improvement in passenger comfort at forward positions. Operation in adaptive and nonlinear modes so that the control deflections are maximized under all conditions give the greatest benefit and can reduce passenger motion sickness incidence (MSI) by up to 25% in a 3-m head sea on the basis of International Organization for Standardization (ISO) recommendations for calculation of MSI for a 90-minute seaway passage.

Time-Domain Analysis of Large-Amplitude Vertical Ship Motions and Wave Loads

10.5957/jsr.1998.42.2.139 ◽

1998 ◽

Vol 42 (02) ◽

pp. 139-153 ◽

Cited By ~ 5

Author(s):

N. Fonseca ◽

C. Guedes Soares

Keyword(s):

Free Surface ◽

Time Domain ◽

Large Amplitude ◽

Surface Condition ◽

Memory Effects ◽

Wave Loads ◽

Strip Theory ◽

Large Amplitude Motions ◽

Free Surface Oscillations ◽

The vertical motions and wave induced loads on ships with forward speed are studied in the time domain, considering non-linear effects associated with large amplitude motions and hull flare shape. The method is based on a strip theory, using singularities distributed on the cross sections which satisfy the linear free surface condition. The solution is obtained in the time domain using convolution to account for the memory effects related to the free surface oscillations. In this way the linear radiation forces are represented in terms of impulse response functions, infinite frequency added masses and radiation restoring coefficients. The diffraction forces associated with incident wave scattering are linear. The hydrostatic and Froude-Krylov forces are evaluated over the instantaneous wetted surface of the hull to account for the large amplitude motions and hull flare. The radiation contribution for wave loads is also obtained in the time domain using convolution to account for the memory effects related to the free surface oscillations. Results of motions and wave loads for the S175 container ship are presented and analyzed. The results from the present method are compared with linear results.

Time Domain Comparison With Experiments for Ship Motions and Structural Loads on a Container Ship in Abnormal Waves

Volume 6: Ocean Engineering ◽

10.1115/omae2011-50316 ◽

2011 ◽

Cited By ~ 12

Author(s):

Suresh Rajendran ◽

Nuno Fonseca ◽

C. Guedes Soares ◽

Gu¨nther F. Clauss ◽

Marco Klein

Keyword(s):

Time Domain ◽

Bending Moment ◽

Green Water ◽

Ship Motions ◽

Container Ship ◽

Wave Elevation ◽

Strip Theory ◽

The Time Domain ◽

Vertical Bending Moment ◽

Comparison With Experiments

The paper presents experimental results from model tests with a containership advancing in abnormal wave conditions and comparisons with numerical simulations. A nonlinear time domain method based on strip theory is used for the calculation of vertical ship responses induced by abnormal waves. This code combines the linear diffraction and radiation forces with dominant nonlinear forces associated with vertical response arising from Froude-Krylov forces, hydrostatic forces and shipping of green water. The time domain simulations are compared directly with experimental records from tests with a model of a container ship in deterministic waves for a range of Froude numbers. Extreme sea conditions were replicated by the reproduction of realistic abnormal waves like the New Year Wave and abnormal wave from North Alwyn. Head sea condition is considered and the comparisons include the wave elevation, the vertical motions of the ship and the vertical bending moment at midship.

Frequency-domain elastic wavefield simulation with hybrid absorbing boundary conditions

Journal of Geophysics and Engineering ◽

10.1093/jge/gxz038 ◽

2019 ◽

Vol 16 (4) ◽

pp. 690-706

Author(s):

Zhencong Zhao ◽

Jingyi Chen ◽

Xiaobo Liu ◽

Baorui Chen

Keyword(s):

Boundary Condition ◽

Free Surface ◽

Boundary Conditions ◽

Frequency Domain ◽

Time Domain ◽

Absorbing Boundary Conditions ◽

Elastic Media ◽

Absorbing Boundary ◽

Wavefield Simulation ◽

Abstract The frequency-domain seismic modeling has advantages over the time-domain modeling, including the efficient implementation of multiple sources and straightforward extension for adding attenuation factors. One of the most persistent challenges in the frequency domain as well as in the time domain is how to effectively suppress the unwanted seismic reflections from the truncated boundaries of the model. Here, we propose a 2D frequency-domain finite-difference wavefield simulation in elastic media with hybrid absorbing boundary conditions, which combine the perfectly matched layer (PML) boundary condition with the Clayton absorbing boundary conditions (first and second orders). The PML boundary condition is implemented in the damping zones of the model, while the Clayton absorbing boundary conditions are applied to the outer boundaries of the damping zones. To improve the absorbing performance of the hybrid absorbing boundary conditions in the frequency domain, we apply the complex coordinate stretching method to the spatial partial derivatives in the Clayton absorbing boundary conditions. To testify the validity of our proposed algorithm, we compare the calculated seismograms with an analytical solution. Numerical tests show the hybrid absorbing boundary condition (PML plus the stretched second-order Clayton absorbing condition) has the best absorbing performance over the other absorbing boundary conditions. In the model tests, we also successfully apply the complex coordinate stretching method to the free surface boundary condition when simulating seismic wave propagation in elastic media with a free surface.

Parametric Rolling Simulations of Container Ships

Volume 9: Odd M. Faltinsen Honoring Symposium on Marine Hydrodynamics ◽

10.1115/omae2013-11344 ◽

2013 ◽

Author(s):

Anton Turk ◽

Jasna Prpić-Oršić ◽

Carlos Guedes Soares

Keyword(s):

Time Domain ◽

Degrees Of Freedom ◽

Equations Of Motion ◽

Full Range ◽

Ship Motions ◽

Computationally Efficient ◽

Parametric Roll ◽

Parametric Rolling ◽

Strip Theory ◽

A hybrid nonlinear time domain seakeeping analysis is applied to the study of a container ship advancing at different headings and encounter frequencies. A time-domain nonlinear strip theory in six degrees-of-freedom has been extended to predict ship motions by solving the unsteady hydrodynamic problem in the frequency domain and the equations of motion in the time domain which allows introducing nonlinearities in the linear model. The code is used to make parametric roll predictions for various speeds and headings and the results are summarized in a very intuitive 2D and 3D polar plots showing the full range of the parametric rolling realizations. The method developed is fairly accurate, robust, very computationally efficient, and can predict nonlinear ship motions. It is well suited to be used as a tool in ship design or as part of a path optimization model.

The Numerical Modeling of Ship Motions and Capsizing in Severe Seas

10.5957/jsr.1990.34.4.289 ◽

1990 ◽

Vol 34 (04) ◽

pp. 289-301

Author(s):

Jan O. de Kat

Keyword(s):

Numerical Modeling ◽

Free Surface ◽

Numerical Model ◽

Nonlinear Model ◽

Time Domain ◽

Ship Motions ◽

First Order ◽

Large Amplitude Motions ◽

Flow Effects ◽

A numerical model has been developed to determine the large-amplitude motions of a steered vessel subjected to severe wave conditions, including those that may lead to capsizing. The model was used to identify different modes of capsizing, and to study relevant mechanisms and conditions. In this paper emphasis is placed on the theoretical aspects. The nonlinear model combines both potential and viscous flow effects, where integrations are carried out in the time domain over the instantaneous free surface; first-order memory effects are taken into account, and the free surface can be irregular, Some new results are presented concerning statistical properties relevant to the simulation of random following or quartering seas.

Numerical Solution of Body-Exact Problem in the Time Domain

10.5957/jsr.2013.57.1.13 ◽

2013 ◽

Vol 57 (01) ◽

pp. 13-23

Author(s):

Wei Qiu ◽

Hongxuan (Heather) Peng

Keyword(s):

Free Surface ◽

Time Domain ◽

The Body ◽

Floating Body ◽

Entire Body ◽

Surface Boundary ◽

Time Step ◽

Submerged Sphere ◽

Wigley Hull ◽

Motions of a floating body in waves are computed in the time domain by solving the body-exact problem with the panel-free method and exact geometry. In the present study, the body boundary condition is imposed on the instantaneous wetted surface exactly at each time step. The free surface boundary is assumed linear so that the time-domain Green function can be applied. The body geometry is represented by NonUniform Rational B-Spline surfaces. At each time step, the instantaneous wetted surface is obtained by trimming the entire body surface. With the panel-free method, the body-exact problems are solved without involving repanelization of the wetted hull surface at each time step. Validation studies have been carried out for a submerged sphere, a flared body, and a Wigley hull. The hydrodynamic forces on the submerged sphere undergoing large-amplitude motion were computed and compared with analytical solutions. For the flared body oscillating in a free surface and the Wigley hull in waves, numerical results were compared with experimental data and solutions by other numerical methods.