ABSTRACT
This paper shows the recent work of the authors in the development of a timedomain FEM model for evaluation of the seal dynamics of a surface effect ship. The fluid solver developed for this purpose, uses a potential flow approach along with a streamline integration of the free surface. The paper focuses on the free surfacestructure algorithm that has been developed to allow the simulation of the complex and highly dynamic behavior of the seals in the interface between the air cushion, and the water.
The developed fluidstructure interaction solver is based, on one side, on an implicit iteration algorithm, communicating pressure forces and displacements of the seals at memory level and, on the other side, on an innovative wetting and drying scheme able to predict the water action on the seals. The stability of the iterative scheme is improved by means of relaxation, and the convergence is accelerated using Aitken’s method.
Several validations against experimental results have been carried out to demonstrate the developed algorithm.
Keywords: surface effect ship; seal dynamics; finite element method; fluidstructure interaction.
The Transformable Craft (TCraft) is a novel ship concept of the US Office of Naval Research, operative in multiple modes. TCraft can deploy in an unloaded condition from the intermediate support base to the seabase, and then be used as a high speed connector to the shore, transporting wheeled and tracked vehicles through the surf zone and onto the beach.
TCraft has been conceived as a SurfaceEffect Ship (SES). A SES is a nonamphibious vehicle supported by an air cushion, with flexible seals at the bow and stern, and twin hulls, like a catamaran, at the sides. Due to the lack of air leakage at the craft sides, lift power can be reduced significantly compared with other type of AirCushion Vehicles (ACV). Also, it is possible to install conventional water propellers or waterjet propulsion, with rather smaller machinery space requirements compared to that for air propellers or fans used on ACVs. Furthermore, the SES can operate in modes of full displacement, partial aircushion support, and full aircushion support.
Predicting the overall performance of a SES is of paramount importance to support the design phase, as the motion of the ship can be affected by the interaction between the air, the cushion, the ship structure, the seals, the sea waves and the sea bottom in the shallow water region. Different approaches with different types of complexity and accuracy have been taken to cope with this type of analyses.
In the last decade, there have been extensive applications of NavierStokes models to naval hydrodynamics problems. For example, Oñate and GarcíaEspinosa [1] presented a stabilized FEM for fluid structure interaction with free surface. In [2] Löhner et al. developed a FEM capable of tracking violent free surface flows interacting with objects. Also GarcíaEspinosa et al. [3] developed a new technique to track complex free surface shapes. More recently, in [4], an application for the calculation of the flow about a SES in still water, using a commercial Volume of Fluid model, has been presented. While, in [5], Mousaviraad et al. uses an URANS solver for evaluating the manoeuvring performance of a SES. While the outcome of the analyses is outstanding, the CPUtime reported in this paper, makes this model quite unaffordable for being used during design stages.
Actually, it is a common consensus that solvers based on the NavierStokes equations are too expensive computationally speaking when it comes to simulate unsteady naval hydrodynamics problems. These sorts of problems can be more efficiently calculated using potential flow theory. This approach, jointly with the Stokes perturbation approximation, is widely used for analysis of seakeeping problems [6]. In [7], Connell et al., uses a boundaryelement timedomain potential flow solver to calculate the multibody seakeeping behaviour of a TCraft SES and a LMSR in different scenarios. While, in [8], the same computational solver is adapted to calculate the manoeuvre of a SES.
Despite the complexity of the above referred SES computational models, none of them takes into account the seal dynamics, or the effect of free surfaceseal interaction. However, it is well known the relevance of this interaction in the unsteady dynamics of a SES [9][10]. The complexity of this phenomenon makes impossible to develop a theoretical background, and prompts many design parameters to be traditionally decided by empirical formulas [9]. Actually, only limited theoretical and computational models have been developed to analyze seal dynamics [11][12][13].
This paper shows an extension of the work presented by ServánCamas and GarcíaEspinosa [6] in the development of an efficient seakeeping solver. In particular, it is focused in the recent work of the authors in the development of a computational model for the analysis of the complex and highly dynamic behavior of the seals in the interface between the air cushion, and the water of a TCraft [14]. The fluid solver developed for this purpose, uses a potential flow approach along with a streamline integration of the free surface. While this approximation is much simpler than using RANS computations, significant outcomes can be obtained as well, allowing to significantly reducing computational time by 2 or 3 orders of magnitude even when computing on a regular desktop or laptop.
The developed fluidstructure interaction solver is based, on one side, on an implicit iteration algorithm, using a TCP/IP sockets link, able to communicate pressure forces and displacements of the seals at memory level and, on the other side, on an innovative wetting and drying scheme able to predict the water action on the seals.
The outline of this paper is as follows. In section 2, we summarize the mathematical modeling and the details of the integration of the fluid equations. Section 3 describes de structural solver. Section 4 introduces the wetting and drying scheme and the fluidstructure interaction solver. In section 5 different validation cases are presented. Finally, we arrive at some conclusions in section 6.
We consider the first order diffractionradiation problem of a ship moving with forward speed . We assume that the flow is incompressible and irrotational, so that the velocity field , is derived from a potential function as: . The following assumptions are made on the order of magnitude of the velocity components and free surface elevation :
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(1) 
Based on the previous assumption, the governing equations for the first order diffractionradiation wave problem on a frame of reference fixed on the ship are:

in Ω
in z = 0 in z = 0 in Γ_{b} in z = H 
(2) 
where is the gradient in the horizontal plane, is the fluid domain, represents the wetted surface of the ship, is the water depth, is the normal of the ship wetted surface pointing outwards the ship, and is the free surface pressure.
The finite element method, FEM, is adopted in this work to solve the second set of equations (2). The FEM statement of the problem is as follows:
Let be the finite element space to interpolate functions, constructed in the usual manner. From this space, we can construct the subspace , that incorporates the Dirichlet conditions for the potential . The space of test functions, denoted by , is constructed as , but with functions vanishing on the Dirichlet boundary. The weak form of the problem can be formulated as:
Find , by solving the discrete variational problem:

(3) 
Where and are the potential normal gradients corresponding to the Neumann boundary conditions on body, free surface and bottom, respectively. At this point, it is useful to introduce the associated matrix form
(4) 
Where is the standard laplacian matrix, and , and are the vector resulting of integrating the corresponding boundary condition term. Further details on the FEM solver can be found in [15].
Solving the free surface boundary condition efficiently is essential when dealing with free surfacestructure interaction (FSSI) problems. The free surface conditions can be rewritten as:

(5) 
where is the base flow. In this work no linearization is assumed since it is considered that . Therefore, the convective velocity will be different in each time step, and the numerical scheme will be adapted accordingly. Three main issues must be kept in mind:
The numerical schemes adopted for solving the kinematicdynamic free surface boundary conditions are based on an implicit midpoint rule for the kinematic condition, and backward Euler for the dynamic condition. Then can be imposed as a Dirichlet boundary condition in the system (3). The schemes read as follows:

(6) 
It is well known that the convective terms appearing in the above equations can result in solutions corrupted by spurious nodetonode oscillations, if no special care is taken when evaluating them. In this work, the convective term is obtained by differentiating along streamlines:

(7) 
where denotes the derivative along the streamline. The streamline derivatives are estimated using a three points upstream and one point downstream differential operator inspired by the work of [16]. The scheme has been conceived to work with unstructured meshes. The use of unstructured meshes enhances geometry flexibility and speed ups the initial modelling time. Furthermore it helps to reduce the number of elements by refining only in those areas of interest. An automatic unstructured grid generator based on the advancing front method is used to generate triangular surface grids and tetrahedral volumetric meshes.
Figure 1 shows the tracing of the streamline at node C. The left (L) and forward left (FL) points are the upstream points, while the right (R) point corresponds to the downstream point. The values of the velocity potential and free surface elevation at L, FL and R points are obtained by linear interpolation between the nodes of the edges where they lie on. The streamline differential operator reads as:

(8) 
where the stencils are obtained as a one dimensional third order finite difference scheme:
(9) 
For the structural model of the seals it has been considered membrane and shell finite elements.
The membrane finite element used in this work is a 3noded membrane triangle. This element uses a total Lagrangian formulation and assumes a linearelastic behaviour of the material [17]. The kinematic description is formulated in large displacements and large deformations, making use of the right CauchyGreen deformation tensor.
The shell finite element used in this paper is a corotational 3noded triangle shell element [18]. The core formulation of the bending part corresponds to a classical Discrete Kirchhoff plate Triangle (DKT). The core formulation of the membrane part corresponds to the Assumed Natural Deviatoric Strain (ANDES) approach [19]. The ANDES formulation represents a linear strain triangle with 3 corner nodes and 3 DOFs per node (two inplane displacements and a drilling rotation).
An energy conserving/decaying timestepping algorithm has been used for the dynamic analysis of the problem [20] [21] [22]. This approach ensures the stability in the nonlinear geometric range.
In general, shell elements are the preferred option to model the seals behaviour, because they can consider the actual flexural rigidity of the seals, despite being small. However, since the thickness of the seals is very small, numerical instabilities can appear. This happens because the tangent matrix is poorly conditioned by the large ratio between membrane and flexural rigidity of the seals. In these cases, the only solution is to neglect the flexural rigidity by using membrane elements. In a dynamic analysis the membrane elements no longer have these problems since the tangent stiffness matrix is properly conditioned by the mass matrix.
Modelling the behaviour of the seals of aircushion vehicles is not a trivial issue, due to the complex interaction of the seals with free surface. In this work, a new algorithm for handling the free surfaceseal interaction problem is formulated. It is based on finding an equivalent pressure field to be applied over the free surface such that the elevation of this one is limited by the location of the seal. That is to say, the seal act as an upper limit for the free surface elevation.
The free surface boundary conditions are applied in different ways depending on whether the free surface is in contact with the seal or not. If the free surface is not in contact, the boundary conditions are applied as if there is no seal, but if there is contact, the implementation will be different in order to ensure that the free surface does not penetrate the seal and the necessary pressure to fulfil this condition is calculated, and imposed as boundary condition on the free surface.
It will be said that the free surface node where the algorithm is to be applied is dry if the seal is not in contact with the free surface at that location, and wet if it is. Figure 2 illustrates the wet and dry concepts.
The main challenge for an algorithm like this is to be capable of capturing when a node goes from dry to wet and vice versa, as well as estimating the pressure field on the wet nodes. Figure 3 shows the wetting and drying iterative algorithm. For a dry node, the implementation of both, the kinematic and dynamic boundary condition is the same as for any other node not interacting with the seal. However, for wet nodes, the free surface boundary condition is imposed via imposing that the free surface elevation matches the seal elevation, , and ensuring that there is no flow across the seal. These two conditions are represented by the following equations:

(10) 
where is to be imposed as Neumann condition instead of imposing as Dirichlet condition.
The change from being a dry node to become a wet node is identified via the kinematic BC though the condition . On the other hand, the switch from being a wet node to become a dry one is carried out by comparing the dynamic pressure with the reference pressure. The dynamic pressure on wet nodes is obtained by the dynamic BC:
(11) 
We found that when the seal is interacting with the free surface, the term might become of the same order of magnitude than . Hence the term has been kept when calculating the pressure on a free surface node in contact with the seal.
The fluidstructure coupling is performed by an implicit interfield iteration algorithm [23], based on a Block GaussSeidel method [24]. For the ith iteration of the current time step n, let , , be the vectors of the velocity potential, free surface elevation and pressure in the corresponding nodes of the fluid, the vector containing the three components of the displacement of the nodes of the seals structure, with the vector of the kth component of the displacement field, and the vector of the elevation field of the seal nodes, then the fluidstructure interaction algorithm, can be written as:
(12) 
Where represent the fluid and solid solver, and p and q are the number of internal iterations done within the nonlinear loop of each solver. This way, the pressure field computed in the hydrodynamic solver is sent to the structural solver to compute the seals deformation. The resulting displacements are used to compute the new seal elevation on the fluid interface, and then calculate the pressure field for the following iteration.
Since the hydrodynamics and structural solvers used in this work are independent, the strategy developed to communicate both is based on the interchange of information at memory level by means of TCPIP sockets. This way, only minor adaptations of the solvers were required. The required functionality has been implemented in C++, in form of library. The communication protocol developed for the library is quite simple. Actually, it just requires sending and receiving functions for vectorial fields, including an implicit waiting instruction in the receiving function for synchronization purposes. Furthermore, this library has been extended to be able to interpolate data between the boundary meshes of the fluid and solid interfaces (see Figure 4). The algorithm to interpolate data between meshes can be summarized as follows:
1) Two octree structures are created to store the seal mesh elements, and the elements of the fluid patch affected by the seal deformation.
2) For every node of the seal mesh, the corresponding octree is used to identify the set of fluid elements where the node is likely to be. For every element of the set, it is checked whether or not the seal node rests on it. As a result of this search, the fluid element in contact with the seal node is selected.
3) Step b) is repeated for every node of the elements of the fluid patch affected by the seal deformation.
4) The shape functions of the selected elements are used to interpolate the information from the fluid to the structure and viceversa. This information is stored in two matrixes; , that allows interpolating the pressure field from the fluid to the seal structure, and , that interpolates the seal deformation field to be used as boundary condition for the fluid flow solver.
Then, the fluidstructure interaction algorithm reads:

(13) 
Even though the iterations within each time step lead to the monolithic solution of the coupled problem, sometimes relaxation techniques are combined with this method to ensure the convergence of the coupling scheme. In this work, a relaxation method based on Aitken’s acceleration has been adopted [25]. Let be the optimal relaxation parameter, obtained via Aitken’s method, the resulting algorithm can be written as:

(14) 
As stated above, the free surfaceseals interaction algorithm is based on finding an equivalent pressure field to be applied over the free surface such that the elevation of this one is limited by the location of the seal. For this purpose, the elevation of the seal over the reference free surface is required. The algorithm (14) assumes that the variation of this elevation is only due to the vertical displacements of the structure. This is a good enough approximation to predict the forces of the water on the seals and the free surface elevation in the seals region.
Zalek and Doctors [26] carried out at University of Michigan an extensive experimental study of free surface and flexible seal interaction. Some of this data has been already used for validation purpose against numerical results based on a smoothed particle hydrodynamics approach [27]. Figure 5 sketches the basic arrangements of the experiments, such as seal length, location of stiffeners and cables and undeflected seal angle. Table 1 provides the seal properties used for the experiments [27].
Thickness  3.175 mm 
Young Modulus  12.74 MPa 
Poisson coefficient  0.25 
Density  1107 kg/m^{3} 
In this work, the experimental cases shown in Table 2 were analysed with the proposed fluidstructure interaction model. The test runs were simulated modelling the left half part of seal and tank, using the actual width and depth of the channel of the University of Michigan. The seals were modelled with shells elements, with the properties provided in Table 1.
Test run [26]  Seal Immersion  Velocity  Internal Pressure  
(in)  (m)  (ft/s)  (m/s)  (in. H_{2}O )  (Pa)  
1  9  0.2286  6  1.8288  1.42  353.3 
10  9  0.2286  8  2.4384  1.01  251.3 
11  9  0.2286  8  2.4384  1.91  475.3 
16  9  0.2286  8  2.4384  4.24  1055 
32  7.5  0.1905  6  1.8288  1.28  318.5 
45  7.5  0.1905  9  2.7432  4.01  997.8 
Table 3 provides the main characteristics of the computational mesh used for the simulation, as well as the length of the numerical channel used. For test run 45, a larger channel was necessary to avoid upstream and downstream interactions with the inlet and outlet boundaries respectively.
Test run  Seal  Water volume  Time step (s)  Domain length (m)  
Number of Nodes  Number of Elements  Number of Nodes  Number of Tetrahedra  
1  234  424  58136  297188  0.002  5.3 
10  234  424  58315  297888  0.001  5.3 
11  234  424  58315  297888  0.001  5.3 
16  234  424  58240  297643  0.002  5.3 
32  234  424  56112  287493  0.002  5.3 
45  234  424  80325  419569  0.001  15.3 
In the experiments, three stiffeners (rods) were fixed to the seal to reduce the transversal deformation of the seals. Since we had no data regarding the properties of such stiffeners, we simulated them by introducing very stiff beams at the same locations, but weightless, assuming that the ones used in the experiments were light enough to avoid significant perturbation in the seal behaviour. Furthermore several cables were attached to the stiffeners rods to avoid the forward displacement of the seal due to the internal pressure. Since there is no available information about the length and exact disposition of these cables, they were simulated in the computational model by a boundary condition, constraining the longitudinal displacement of the points of the seal where the cables were attached.
Figure 6 shows the quasisteady deformed front seal and free surface elevation respectively for test run number 10. Figure 7 compares the average seal deformation obtained numerically and experimentally. Although the computational results do not match exactly the experimental ones, they agree well in terms of the main trends under different conditions of velocity, seal immersion and internal pressure. Anyhow, the differences are probably within the uncertainty range of the data, since the unsteady and threedimensional effects are relevant in most of the studied cases.
Figure 8 provides the top view of the hydrodynamic pressure distribution acting on the seal due to the free surface seal interaction. It can be observed that while in some cases the distribution is almost uniform in the transverse direction it is not in others, resulting in relevant three dimensional effects, as mentioned before.
Wiggins et al. [28] developed a large scale testing platform for finger bow seals at the U.S. Navy´s Large Cavitation Channel. The purpose of those test were to provide experimental results to be used for validation purposes of analytical/numerical approaches to the problem. Figure 9 sketches the model setup at the LCC facilities
The seal material used is the same one that the one used in the University of Michigan experiments and described in the previous section. In this case, a membrane model was used for the computational analysis of the structure, since preliminary tests with a shell model showed an unstable behavior, probably due to the poor condition of the tangent matrix.
With regards to the test condition, we used a free stream flow of 6 m/s, seal immersion of 15 cm, and internal pressure of 1.5 kPa [28]. Other data needed for the setup of the case under study are provided in Table 4.
Breadth of cushion (m)  1.52 
Sidewall depth (m)  1.68 
Sidewall draft at zero immersion (m)  0.42 
Channel width (m)  3.05 
Number of Fingers 5  5 
Finger height (m)  1.00 
Finger width (m)  0.31 
Bow seal angle (º)  50.00 
Table 5 provides the main characteristics of the computational mesh used for the simulation, as well as the length of the numerical channel used. Figure 10 shows the computational mesh used for solving the fluid problem.
Fingers  Number of Nodes  7023 
Number of Elements  13436  
Water domain  Number of Nodes  120942 
Number of Tetrahedra  659687  
Time step (s)  0.0005  
Domain length (m)  21 
Figure 11 (a) shows the steady seal deformation obtained in the experiments under the abovementioned test conditions. Figure 11 (b), (c) and (d) show seal deformation obtained by the numerical approach proposed in this work under the same test conditions. Free surface elevation at the seal and aircushion areas are shown in Figure 12 (a). A top view of the pressure distribution over finger seals is shown in Figure 12 (b).
As can be seen, the bow seals deformation obtained in this analysis agrees with the qualitative experimental information available in reference [28]. In fact, the deformation mode obtained in the computational model is quite similar to that found experimentally.
This paper reports the advances in the development of a fluidstructure interaction algorithm for evaluation of a SES seal dynamics.
The fluid solver developed for this purpose, uses a potential flow approach along with a streamline integration of the free surface. The work has been focused on the FSSI algorithm that has been developed to allow simulating complex and highly dynamic behavior of the seals in the interface between the air cushion, and the water.
The developed fluidstructure interaction solver is based, on one side, on an implicit iteration algorithm, communicating pressure forces and displacements of the seals at memory level and, on the other side, on an innovative wetting and drying scheme able to predict the water action on the seals. The seal dynamics are solved using a Lagrangian FEM formulation for a 3noded membrane/shell triangle.
Special care has to be taken to ensure the convergence of the fluidstructure interaction algorithm due to the highly flexible and nonlinear nature of the seal. We found that relaxation method based on Aitkens acceleration methods worked well under all the case studies analysed.
Different validation and demonstration cases have confirmed the validity of the approach to study the complex dynamic behaviour of the seals.
This work relates to Department of the Navy Grant N629091017053 issued by Office of Naval Research Global. The United States Government has a royaltyfree license throughout the world in all copyrightable material contained herein.
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Published on 01/02/17
Accepted on 01/02/17
Submitted on 01/02/17
Licence: CC BYNCSA license
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