Latest revision as of 16:23, 5 October 2023

Abstract

The internal solitary waves (ISWs) in the ocean carry huge energy and pose a serious threat to the safety of underwater vehicle. In order to obtain the dynamic response of the submarine under the action of ISWs, the amplified SUBOFF model was placed in a large numerical water tank with a length of 5000m, a width of 200m and a depth of 500m. The Korteweg-de Vries (KdV) theory was adopted to simulate the generation of ISWs in the two-layer flow, and overset grid technology was used to ensure the grid quality during the submarine movement. The results show that before the ISWs peak reaches the position of the submarine, the submarine will move, which causes the submarine to sink, move laterally and pitch. The longitudinal velocity is obviously greater than the lateral velocity, and the submarine finally hits the water tank bottom. With the increase of the ISWs amplitude, the time needed for submarine to reach the bottom increases, and the pitching angle increases greatly. The ISWs amplitude has no effect on the motion trajectory of the submarine's center of gravity, and has little effect on the lateral and longitudinal velocity. With the decrease of submergence depth of the submarine, the time required for submarine to reach the bottom will also increase, and the motion trajectory will change, but the trend of change is basically the same. The submergence depth has little influence on the variation range of lateral velocity, longitudinal velocity and pitching angle.

Keywords: internal solitary waves, submarine, dynamic response, numerical simulation

1. Introduction

Internal solitary waves (ISWs) are common phenomenon in the stratified ocean, which has the characteristics of medium-fine scale, large amplitude and strong velocity [1]. The shear currents and turbulence generated by ISWs contribute to global energy transport and dissipation in the ocean, but also affect biological activities, offshore engineering and submarine navigation [2]. Due to the development of ISWs below the sea surface, low propagation frequency and long distance, it is difficult to observe them which seriously threaten the safety of ocean engineering structures and underwater vehicle [3].

In view of the influence of ISWs on ocean engineering and underwater vehicles, the current research focuses on the monitoring of ISWs [1,4], and the simulation of ISWs [3,5], as well as the influence of ISWs on submerged tunnels [6], semi-submersible platforms [7-8] and submarines [9-11]. Research on the interaction between ISWs and submarines has focused on the standard submarine model proposed by the Defense Advanced Research Projects Agency (DARPA), known as the DARPA SUBOFF model [12]. CHEN studied the submarine load variation induced by ISWs with and without submarine speed [9]. LI used the numerical model of ISWs in a continuously stratified fluid, numerically analyzed the forces and moments of SUBOFF when it encountered ISWs in different submergence depths, discussed the influence of rotation center position on the moment, and proposed the optimal rotation center position [10]. GUAN numerically studied the hydrodynamic properties and load characteristics of submarine when it encountered ISWs in the ocean [11].

It is worth noting that in the above studies, the freedom of the submarine is constrained when the submarine encounters the ISWs. The submarine position is fixed and in a static state. As matter of fact, the submarine will inevitably move or even sink when it encounters the ISWs. So the submarine movement must be taken into account in the research. DU studied the kinematics characteristic and the mass center trace of the slender model in the density stratification fluid with a semi-flexible restriction technique, and obtained the properties such as heave, surge, roll, pitch, but the slender body was bound by the flexible line in the water tank [13]. CUI used experimental methods to study the dynamic response of submerged body under the action of ISWs, and obtained the influence of different wave amplitudes, the thickness ratio of the upper and lower layers of fluid, and the shape of the submarine section, etc. Strong currents in the horizontal and vertical directions caused by ISWs can greatly move submerged body and cause damage to its structure. Limited by the experimental tank, the section of the submerged model is less than 10cm [14]. In general, the submerged body is affected by ISWs, which will lead to lateral, longitudinal and pitching motions.

In order to simulate the situation of large submarine encountering ISWs in the ocean, a large numerical tank and a large submarine model are constructed by numerical simulation method, and the dynamic response of submarine under the action of ISWs is studied in a numerical tank with continuous density changes.

2. Simulation configurations

2.1 Submarine model

The standard submarine model of Defense Advanced Research Projects Agency (DARPA), which called DARPA SUBOFF, has an overall length of 4.356m and a maximum diameter of 0.508m, as shown in Figure 1(a). The SUBOFF model itself is small in scale, so a 1:25.5 scale of DARPA SUBOFF is used to simulate the actual submarine. In order to ensure the quality of the grids, the grids in the submarine appendage area must be refined and the time step must be reduced to ensure a reasonable Courant number, which consumes more computational resources. However the main purpose of this work is to study the free motion of the submarine and the influence of appendages on free motion is minimal. Here, the model used in this work was simplified and the appendages of SUBOFF model were removed, as shown in Figure 1(b). The enlarged bare hull has an overall length of 111m and a maximum diameter of 12.954m. The gravity center of the submarine is placed on the axis of the hull, 51 m away from the bow.

(a) DARPA SUBOFF model (b) SUBOFF simplified model

Figure 1. SUBOFF model

2.2 Numerical flume

The numerical flume is shown in the Figure 2 and has a total length of 5000 m, width of 200 m and depth of 500 m, including the working zone which has a length of 4000 m and the wave damping zone which has a length of 1000 m. The fluid densities of the upper and lower layers are different. The density varies continuously along depth in each layer of fluid, as shown in Figure 3. The Dimensionless density means the density/ ${\textstyle 1000.00}$ kg/m${\textstyle ^{3}}$. The upper layer fluid density ${\textstyle {\rho }_{1}}$ varies from ${\textstyle 997.00}$ kg/m${\textstyle ^{3}}$ to ${\textstyle 997.50}$ kg/m${\textstyle ^{3}}$ and the lower layer fluid density ${\textstyle {\rho }_{2}}$ varies from ${\textstyle 1034.00}$ kg/m${\textstyle ^{3}}$ to ${\textstyle 1036.00}$ kg/m${\textstyle ^{3}}$. The depth of the upper and lower fluid are 100m and 400m, respectively.

Figure 2. Sketch of numerical flume

Figure 3. Change of density along the water depth

The distance between submarine location and the two layers interface is defined as the submergence depth H. The inlet and outlet are on the left side of the flume. Speed entrance method is adopted to make the numerical wave and pressure boundary condition is inducted for outlet. The inlet boundary is set by the user-defined function (UDF), which produces the ISWs. The bottom, top and right of the flume are all using the solid wall boundary.

2.3 ISW theory

The Korteweg-de Vires (KdV) equation has a wide range of applications for small amplitude and weak nonlinear ISWs [3]. For the numerical flume established in this paper, the ratio of wave amplitude to the depth of the flume ${\textstyle {\eta }_{0}/(h_{1}+h_{2})<0.1}$ (${\textstyle {\eta }_{0}}$ is the ISW amplitude), so the KdV theory can be used [15]. The propagation of a wave along the horizontal x direction is expressed as [16-17]:

where ${\textstyle c_{0}}$, ${\textstyle c_{1}}$ and ${\textstyle c_{2}}$ are the linear phase speed, nonlinear coefficient, measure of dispersion respectively, which can be wright as：

The KdV expression for the ISW is:

The soliton velocity and characteristic wavelength based on KdV theory are:

2.4 Meshing scheme and simulation method

(1) Meshing scheme

The submarine will move horizontally and vertically, accompanied by pitching motion which affected by ISWs, as shown in Figure 4. The moving mesh is easy to be generated with negative volume, and the grid update takes a long time, resulting in a very long computation time. So the overset mesh technology is adopted in this paper. A separate component mesh was constructed in the SUBOFF region, the size of which was 160 m×20 m×60 m. The unstructured grids were adopted with total grids of 1.42 million. In addition, structured grid was used in the flume as the background grid with total grids of 5.31 million, as shown in Figure 5. In the overlapping regions, the overset interfaces connect cell zones by interpolating cell data. The overset mesh method can maintain mesh quality well during submarine motion.

Figure 4. Sketch of submarine motion

(a) Unstructered grids around the SUBOFF (b) Sketch of overset mesh

Figure 5. The computational grid in the domain

(2) Simulation method

The unsteady Reynolds- Averaged Navier-Stokes equations with the ${\textstyle k-\epsilon }$ turbulence model are applied to simulate the flow field. The ${\textstyle k-\epsilon }$ turbulence added two variables to the governing equation which are turbulence kinetic energy ${\textstyle k}$ and dissipation rate of turbulence kinetic energy ${\textstyle \epsilon }$. ${\textstyle k}$ represents the change of velocity fluctuation and ${\textstyle \epsilon }$ represents dissipation rate of velocity fluctuation. The mass continuity equation and momentum equation are shown as follows:

where ${\textstyle {\mu }_{\mbox{eff}}}$ is effective viscosity, ${\textstyle p^{'}}$ is the modified pressure, and ${\textstyle S_{M}}$ is the sum of body forces.

The ${\textstyle k}$ and ${\textstyle \epsilon }$ can be solved by following equations:

where ${\textstyle {\sigma }_{k}}$ and ${\textstyle {\sigma }_{\epsilon }}$ are Prandtl numbers corresponding to turbulence kinetic energy and dissipation rate, respectively; ${\textstyle P_{k}}$ is the turbulence production due to viscous forces; ${\textstyle C_{\epsilon 1}}$ and ${\textstyle C_{\epsilon 2}}$ are constants; ${\textstyle \mu }$ is the dynamic viscosity and ${\textstyle {\mu }_{\mbox{t}}}$ is the turbulent viscosity.

The ISW wave surface was tracked by Volume of fluid (VOF) method [18]. The fluid’s volume fraction ${\textstyle {\alpha }_{i}}$ represents the ratio of the ${\textstyle i^{th}}$ fluid’s volume in a cell to the total volume of the cell. For the ${\textstyle {\alpha }_{i}}$, the equation has the following form：

For every control volume, the volume fractions of all phases sum to unit. When ${\textstyle {\alpha }_{i}=1}$, the cell is full of the ${\textstyle i^{th}}$ fluid; when ${\textstyle {\alpha }_{i}=0}$, the cell is empty of the ${\textstyle i^{th}}$ fluid; when ${\textstyle 0<{\alpha }_{i}<1}$, the cell contains the interface [19]. For the two-layer fluid in this paper, ${\textstyle i=1}$ or 2.

3. Numerical results and discussions

The submarine is located in the numerical flume and the distance between the gravity center and the flume inlet is 1500 m. The submarine is in a state of equilibrium with its own buoyancy. The power of the submarine is not taken into account, so it has no initial speed and its freedom of motion is not constrained.

In order to study the interactions between different ISWs and submarine, three ISW amplitudes and two submergence depths are used in this part, which include ${\textstyle {\eta }_{0}=10}$m, ${\textstyle {\eta }_{0}=20}$m, ${\textstyle {\eta }_{0}=30}$m and ${\textstyle H=45}$m, ${\textstyle H=15}$m, as shown in Table 1.

The case C31 was selected to verify the numerical flume established in this paper, and the formation of ISWs was monitored at x=1500m. As can be seen from Figure 6, the wave generation of the numerical flume was highly consistent with that of KdV theory, which met the requirements of numerical simulation.

Figure 6. Numerical result verification

3.1 Trajectory of submarine motion

The initial submergence depth of SUBOFF was 45m or 15m below the interface. When the ISWs flow field was formed by the numerical flume, the motion of the submarine was observed. Figure 7 shows the motion trajectory of SUBOFF's center of gravity under different submergence depths. As can be seen from Figure 7, no matter the depth is 45m or 15m, SUBOFF's center of gravity moved in a similar trajectory, moving to the lower left under the influence of the ISWs. And the longitudinal displacement was significantly greater than the lateral displacement. Restricted by the size of the numerical flume, SUBOFF rebounded after impacting the bottom of the flume, and then continued to move to the upper left. At the same depth, the ISWs amplitude had no effect on the trajectory of submarine motion. Different wave amplitudes had no effect on the position of the impact point of SUBOFF, and the trajectory of the submarine basically coincided after rebound.

(a) ${\textstyle H=45}$m (b) ${\textstyle H=15}$m

Figure 7. Trajectory of submarine motion

The change of submarine longitudinal position with time is shown in Figure 8. For the first 100s, SUBOFF kept its position unchanged. Because the flow field of ISWs had not reached the zone where the submarine was located, and the submarine was in a state of equilibrium. Then it began to dive under the influence of the ISWs flow field, and finally hit bottom and rebounded. As can be seen from Figure 8, with the increase of ISWs amplitude, the time required for the submarine to reach the bottom was longer, and the time required for C11, C21 and C31 to reach the bottom were 269s, 278s and 282s, respectively. So with the higher ISW amplitude, the submarine longitudinal velocity reduced. According to KdV theory, the ISWs speed decreased with the increase of the ISWs amplitudes, which was the reason for the change of submarine bottoming time. The position of the submarine was 1500m away from the flume inlet, and it took less than 300s for the submarine sink more than 300m. It can be seen that the ISWs can cause serious damage to the submarine.

(a) ${\textstyle H=45}$m (b) ${\textstyle H=15}$m

Figure 8. Change of submarine longitudinal position with time

In order to compare the influence of different submergence depth on the submarine motion trajectory, C31 and C32 with a wave amplitude of 30m were selected, as shown in Figure 9. The distance between the submarine and the flume bottom became greater with the decrease of the submergence depth, which lead to the lateral displacement was greater when the submarine hit the bottom, and the longitudinal displacement was smaller after the rebound which was affected by the ISWs. As can be seen from Figure 9(b), as the depth ${\textstyle H}$ decreased, the time required for the submarine to reach the bottom increased.

(a) Motion trajectory (b) Longitudinal position change with time

Figure 9. Trajectory of submarine motion with different ${\textstyle H}$

It is well known that the submarine will be dragged into the seabed by ISWs, and the impact on the bottom will produce strong load and lead to serious damage to its structure. The data after the rebound on the bottom has little significance. Therefore, this paper focuses on the analysis before the submarine hits the bottom.

3.2 Characteristics of the motion

The motion characteristics of the marine in the flume were studied when the wave amplitude was 20m and the submergence depth was 15m (C22). Figure 10 shows the movement of SUBOFF at six moments before it hits the bottom. The color mark the upper and lower layers of fluid with different densities respectively, and the submarine is below the interface. During the first 100s, the position of the submarine remained basically unchanged. After that, the submarine began to sink, and Figure 10(d) showed obvious sinking of the submarine. At ${\textstyle t=200}$s, it can be seen that the submarine was starting to pitch, the submarine's bow was up. At ${\displaystyle t=250}$s, the change of pitching and sinking was obvious. At this time, the ISWs peak has not reached the location of the submarine. The flow field formed by ISWs had a strong influence on the submarine before the peak of the ISW reached the position of the submarine, resulting in not only submarine transverse and longitudinal displacement but also the pitching.

(a) 0s (b) 50s (c) 100s (d) 150s (c) 200s (d) 250s

Figure 10. Submarine motion characteristics at different times

3.3 Motion parameters

(1) The effect of different ISWs amplitudes

The lateral velocity of the submarine under different ISW amplitudes is shown in Figure 11. After ${\displaystyle t=100}$ s, the absolute lateral value of velocity increased along the negative ${\displaystyle x}$-direction. Under the same submergence depth, lateral acceleration decreased with the increase of wave amplitude. When ${\displaystyle H=45}$m and ${\displaystyle t=260}$s, the lateral velocities of C11, C21 and C31 were -0.51 m/s, -0.41 m/s and -0.39 m/s, respectively. By comparison with Figure 11(a) and Figure 11(b), it is found that the submergence depth has little influence on the lateral velocity variation trend.

(a) ${\textstyle H=45}$m (b) ${\textstyle H=15}$m

Figure 11. Lateral velocity at different ISW amplitudes

The longitudinal velocity of the submarine under different depths is shown in Figure 12 . Similar to the lateral velocity, the longitudinal velocity increased along the negative y-direction, and the change of longitudinal velocity was one order of magnitude larger than that of the lateral velocity. Before ${\displaystyle t=180}$s, the submarine was accelerating longitudinally. After ${\displaystyle t=180}$s, the longitudinal velocity began to keep basically stable at about -2.5m/s.

(a) ${\textstyle H=45}$m (b) ${\textstyle H=15}$m

Figure 12. Longitudinal velocity at different ISW amplitudes

The pitch angle of the submarine under different ISW amplitudes is shown in Figure 13. When the submergence depth was 45m, as shown in Figure 13(a), the submarine basically keeps level without pitching before ${\displaystyle t=180}$s; after ${\displaystyle t=180}$s, the submarine began to pitch. The pitch angle gradually increased with time, and the pitch angle variation decreased with the increase of ISW amplitudes. When ${\displaystyle t=260}$s, the pitch angles of C11, C21 and C31 were -21.10°, -17.16° and -14.50°, respectively. When the submergence depth ${\textstyle H=15}$m, the changes of pitch angle were similar to ${\textstyle H=45}$m.

(a) ${\textstyle H=45}$m (b) ${\textstyle H=15}$m

Figure 13. Pitch angle at different ISW amplitudes

(2) The effect of submergence depths

Figure 14 shows the comparison of the submarine velocity under different submergence depths. When the wave amplitude was constant, the influence of the submergence depth on the change of the lateral velocity and longitudinal velocity can be ignored.

(a) Comparison of lateral velocity (b) Comparison of longitudinal velocity

Figure 14. Comparison of velocity at different depths

The variations of pitch angle with time at the same wave amplitude but different submergence depths are shown in Figure 15. As shown in the figure, submergence depths had little influence on the variation of pitch angle.

Figure 15. Comparison of pitch angle at different depths

4. Conclusions

The dynamic response of large submarine induced by ISWs was simulated by establishing the ISWs numerical flume. The flume was a stratified fluid of two layers, and the fluid density varied with the depth which was more in line with the actual ocean. The track of gravity center, variations in lateral, longitudinal and pitch motion are studied. The conclusions of this study are listed as follows:

(1) When the submarine is located under the two-layer interface, the submarine moves to the lower left, then impacts on bottom and rebounds which is affected by ISWs. The submarine motion trajectory and the impact location are not affected by the initial submergence depth.

(2) The ISW amplitude also affects the time for the submarine impacting the flume bottom, and as the ISW amplitude increases, the longer the time is required.

(3) The submarine will move which is affected by ISWs. The longitudinal velocity is bigger than lateral velocity. The motion of the submarine is accompanied by pitching. The influence of submergence depth on the submarine lateral velocity and longitudinal velocity is negligible. Before the submarine reaches the bottom, the horizontal velocity is increasing. The higher the ISW amplitude, the smaller the longitudinal velocity is. The longitudinal velocity also accelerates first, and then the value fluctuation is maintained. In the process of the sinking, the pitch angle gradually becomes larger, and the pitch angle decreases as the ISW amplitude increases. The changes in the pitch angle are not affected by the submergence depth.

Acknowledgments

This work was supported by Natural Science Foundation of Sichuan Province of China No. 2022NSFSC0478, CAFUC Foundation J2022-035 and Foundation of Key Laboratory of Flight Techniques and Flight Safety，CAAC, FZ2020ZZ05.

Conflict of interest statement

The authors declare that there are no conflict of interests, we do not have any possible conflicts of interest.

References