Simulation-based uprighting of a capsized ship in wave-induced environments

Over the last few years, the worldwide shipping business and sea-related traffic have gotten busier and busier [1], stimulated by the recovery of trade and strong demand for commodities. This situation speeds up the launch of ships. The scale of the world’s fleet has been increasing, and ship accidents have increased significantly. Many ships have capsized due to the loss of stability.

Serious accidents often occur after the ships lose their stability. The main factors affecting the stability of the ship are the position of the ship’s center of gravity, the marine environment, the positions of the cargo and the operation error [2]. The fuzzy analytic hierarchy process (FAHP) was used to analyze the hydrostatic mechanical properties of ships by Thaddeus C. NWAOHA and Fabian I. IDUBOR. The effects of ship shape, draft and weight on ship stability were analyzed in detail [3]. Cristian-Milică Niţă used Modelmaker software to study the influence of ship shape and ballast tank size on ship stability [4]. Borlase studied the stability of different structures under different loads [5]. Weidle W S studied the influence of geometric parameters of a single ship, catamaran and trimaran on the stability of intact ship and damaged ship and obtained the effect of waterline area on ship stability [6]. Karimirad M and Michailides C studied the static stability of different types of semi-submersible offshore wind turbines and found that the restoring moment can be improved by changing the stability height [7].

Changes in underwater volume affect the stability of the hull. Sun et al. evaluated the stability of the damaged ship by using the loss buoyancy method, volume change method and Newton iteration method. They obtained the effect of the liquid level height of the tank and the floating parameters of the hull when the ship was in any floating states [8]. Degan et al. studied the seaworthiness of large-scale ships through methods of the multi-attribute decision making (MADM) and mathematical design model (MDM) and obtained the calculation method of ship stability through a large number of analyses. The error between the calculation results and the actual results is small [9]. The movement of the floating body load will cause a change in stability. Due to the effect of inertia, the speed of load movement on the floating body should be limited [10]. For a long time, a large number of studies have been carried out on the stability of normal ships, while there are few studies on the stability of complex structures. For example, the underwater shape of the hull changes continuously in the uprighting process of a capsized ship, which increases the difficulty of analyzing the stability of the ship [11, 12]. Varsami used a Trainer 5000 simulator to simulate the salvage process of a stranded ship and obtained the change in hull stability [13].

Under the action of wave force, not only the force distribution and direction of the floating body are changed, but also the stability of the floating body. Both tidal waves and air pressure waves will reduce the ship’s stability, cause the ship to sway or tilt and make the ship deviate from the equilibrium state [14]. Manderbacka et al. discussed the effects of different wave parameters on ship stability based on different cases [11]. Ueng put forward a static method to calculate the stability and buoyancy of ships and further deduced the calculation methods of heave, pitch and roll motions of ships, which can be used for ship motion simulation [3]. Through simulation analysis, Armudi et al. found that both wave velocity and wave height had significant effects on ship drift [15]. Ermina Begovic et al. studied the change of hull stability caused by the change of hull position in waves [16]. Petacco studied the effects of hull volume distribution, hull weight distribution and wave profile on hull stability [17]. For the floating body with a special underwater shape, it is difficult to accurately solve the analytical solutions of wave first-order and second-order potentials and their external forces [18]. Gu et al. studied the motion of paralyzed ships under sea waves through experiments and simulations. Their results show that the probability of inclination of the paralyzed ship with drift motion is higher than that of the paralyzed ship without drift motion [19].

The simulation calculation of wave force is helpful to determine the motion of the floating body. With reference to the Harbour hydrological code (Chian), Li and Shi calculated the wave force of the towing systems. The calculation method has high accuracy when applied to low-speed structures [20]. Yu et al. compared the motion of a jack-up drilling platform in waves through test and simulation calculations. The error rate between the simulation results and the test results is less than 10%, which shows that the numerical simulation method can better simulate the motion response of this platform [21]. When Pekka Ruponen used Archimedes law to calculate the wave force of the hull, the hull surface was divided into several panels, and the buoyancy was obtained by integrating the pressure on the panels. This method is also suitable for analyzing the ship motion in waves and for the stability analysis of offshore structures with complex geometry [22]. In order to calculate the motion of the ship in waves, Kuang Ueng et al. regarded the hull as a rigid body, assuming that the motion amplitude of the hull is small, and the six degrees of freedom are independent and superimposed to describe the motion of the hull [23]. Cien and Tey adopted the statics method to calculate the floating state and stability of the floating platform for marine agricultural microalgae and further studied the influence of scale and wave frequency on the tilt angle of the floating platform [24]. Armudi et al. used numerical analysis methods to study the motion law of ships under the action of linear and nonlinear waves. The results show that waves seriously affect the ship’s motion [25].

Many salvage projects are operated when the waves are small and the impact of the swell is ignored while formulating the uprighting scheme [26, 27]. However, sometimes swell can also have a non-negligible impact on the hull, so it is necessary to study the impact of swell on the uprighting process [28]. Based on previous research, this paper focuses on the calculation of the influence of swell on the uprighting process, establishes the mechanical model of righting a capsized ship considering the swell effect and clarifies the influence of the encounter angle on the hull. Furthermore, GHS software is used to simulate the uprighting process of the capsized ship in seven environments. The influences of a calm sea environment, wave environment and encounter angle on the uprighting process of the capsized ship are analyzed.

In view of the influence of waves on the uprighting process, the calculation method of the righting force and righting force moment is derived. In order to determine the effect of swell on a capsized ship under three-level sea conditions, the righting force and righting force moment of different ship headings are compared, and the encounter angle suitable for righting a capsized ship is obtained. Furthermore, the dangerous positions of the hull and the influence of the wave direction on the longitudinal strength of the hull are determined by analyzing the mechanical distribution of the hull, which provides a theoretical reference for the uprighting process in the swell environment.

This paper consists of five parts. The first part is literature research, including ship floating state research, ship static stability research, wave force research and the effect of waves on uprighting process research. The second part is the mechanical analysis of the capsized ship, including the wave force model, the force analysis of the hull and the solution of the righting force. The third part is the simulation of the uprighting process of the capsized ship. The fourth part is the analysis and discussion of the hull stability, the righting force, the righting force moment and the longitudinal strength of the hull. The fifth part belongs to the conclusion.

While designing the righting scheme of a capsized ship, we should not only pursue reducing the righting force and righting force moment but also pay attention to reducing the damage to the hull. By analyzing the maximum shear force value, maximum bending moment value and maximum torque value of the hull under various working conditions, the stress changes of the hull during the uprighting process can be predicted, which is convenient for arranging the salvage construction workshop in advance. In order to express the force range of all parts of the hull in the uprighting process, the shear force, bending moment and torque of each part of the hull are calculated and compared in detail.

To study the influence of waves on the uprighting process of a capsized ship, a mechanical model of righting force is established based on previous literature. By simulating the uprighting process of the capsized ship in different environments, the conclusions can be drawn as follows.

The shear force of the ship in the calm sea environment and wave environment is quite different. When the wave encounter angle is at 0°, the shear force of some positions of the ship is 2–3 times that of the calm sea environment. Therefore, it is necessary to consider the effect of waves on the ship in the process of righting the capsized ship. And, the shear force at the same position of the ship may vary greatly with different wave angles. When the wave encounter angle is at 0°, the shear force value of some positions of the ship is 3–4 times that of the 300° environment. Therefore, adjusting the angle between the ship and the wave and the direction of righting the capsized ship can effectively reduce the damage of the wave to the ship.

In the uprighting project, the wave encounter angle will significantly affect the bending moment distribution, and the bending moment value of individual locations can be changed by more than 200%. In the environment with encounter angles at 0°, 60°, 180° and 240°, the variation trends of the maximum and the minimum bending moment curves of the hull are consistent, and the variation range of the bending moment value is larger than that in other cases. Therefore, the encounter angle should be avoided from being close to the above angle, or the encounter angle of the hull should be avoided from being close to the above angle for a long time.

When the encounter angles are at 60° and 120°, the variation range of hull torque value is large during the uprighting process. The negative torque generated near the superstructure is large, while the positive righting force moment needed to be applied in the uprighting process is small. It shows that the local position of the ship under these two conditions makes it easy to produce a large torque value, but the total torque value of the ship is relatively small. When the encounter angle is at 300°, the negative torque value of the ship changes little, but it needs to apply a relatively large righting force moment during the uprighting process. Under this condition, the righting force moment is not large, and the position of the righting force point should be changed.