Shallow water sloshing in rotating vessels


 Department of Mathematics
 University of Surrey
 UK

   
Shallow water sloshing in rotating vessels - 2D flowfield
   
  New shallow-water equations, for sloshing in two dimensions (one horizontal and one vertical) in a vessel which is undergoing rigid-body motion in the plane, are derived. The planar motion of the vessel (pitch-surge-heave or roll-sway-heave) is exactly modelled and the only approximations are in the fluid motion. The flow is assumed to be inviscid but vortical, with approximations on the vertical velocity and acceleration at the surface. These equations improve previous shallow water models for sloshing. The model also contains the essence of the Penney-Price-Taylor theory for the highest standing wave. The surface shallow water equations are simulated using a robust implicit finite-difference scheme. Numerical experiments are reported, including simulations of coupled translation-rotation forcing, and sloshing on a Ferris wheel. Asymptotic results confirm that rotations should be of order h/L, where h is the mean depth and L is the vessel length, but translations can be of order unity, in the shallow water limit.
   
  H. Alemi Ardakani & T.J. Bridges. Shallow-water sloshing in rotating vessels undergoing prescribed rigid-body motion in two dimensions. European J. Mech. B/Fluids 31 30-43   Journal Website
   
  H. Alemi Ardakani & T.J. Bridges. Shallow-water sloshing in rotating vessels undergoing prescribed rigid-body motion in two dimensions -- the extended version. Technical Report     (2010)
  H. Alemi Ardakani & T.J. Bridges. Comparison of the numerical scheme with previous rotating SWE numerics of Dillingham, Armenio & La Rocca, Huang & Hsiung Technical Report, (2010)    
   
     Video1.mpg    Video2.mpg    Video3.mpg    Video4.mpg

Shallow water sloshing in rotating vessels - 3D flowfield
   
  New shallow-water equations, for sloshing in three dimensions (two horizontal and one vertical) in a vessel which is undergoing rigid-body motion in 3-space, are derived. The rigid-body motion of the vessel (roll-pitch-yaw and/or surge-sway-heave) is modelled exactly and the only approximations are in the fluid motion. The flow is assumed to be inviscid but vortical, with approximations on the vertical velocity and acceleration at the surface. These equations improve previous shallow water models. The model also extends the essence of the Penney-Price-Taylor theory for the highest standing wave. The surface shallow water equations are simulated using a split-step implicit alternating direction finite-difference scheme. Numerical experiments are reported, including comparisons with existing results in the literature, and simulations with vessels undergoing full three-dimensional rotations.
   
  H. Alemi Ardakani & T.J. Bridges. Shallow-water sloshing in vessels undergoing prescribed rigid-body motion in three dimensions, J. Fluid Mech. 667 474-519 (2011)    
  H. Alemi Ardakani & T.J. Bridges. Shallow-water sloshing in vessels undergoing prescribed rigid-body motion in three dimensions Technical Report (2009)   (extended version with colour figures)  

Shallow water sloshing on the London Eye
   
  The London Eye is a large ferris wheel and pictures of it can be found at their website (click here) . The object here is to study the sloshing of a partially filled vessel attached to the wheel. Mathematically, the vessel is prescribed to travel along a circular path. Even when the speed along the path is constant, sloshing occurs due to change in direction. The base of the vessel remains horizontal along the path. In addition the vessel can also have a prescribed rotation. The interest in this example is threefold. It is an example with very large displacements of the vehicle and illustrates the generality of the prescribed vessel motion. Secondly, it is a prototype for the transport of a vessel along a surface. In this case the surface is a circle. As the vehicle moves along the surface it can also rotate relative to the point of attachment. Other examples of surfaces of interest are a sphere or near sphere, which is a model for a satellite containing fluid and orbiting the earth, and a surface modelling terrain. The latter is a model for vehicles transporting liquid on roads through hilly terrain. Thirdly, it is an excellent setting to test control strategies for sloshing. For example, suppose the speed along a path in the surface is prescribed. Sloshing will result if the path is curved due to induced acceleration. The local rotation of the body could act as a control, and roll, pitch or yaw could be induced to counteract any sloshing due to motion along the path. This example is discussed in the above papers.
   
  Videos of fluid-vehicle interaction

Video6.mpg    Video7.mpg    Video8.mpg    Video9.mpg    Video10.mpg    Video11.mpg

Parameter values associated with the above videos

Dynamic coupling between fluid sloshing and vehicle motion
   
  The coupled motion between shallow water sloshing in a moving vehicle and the vehicle dynamics is considered. The movement of the vessel is restricted to horizontal motion. Motivated by the theory of Cooker (1994), a new derivation of the coupled problem in the Eulerian fluid representation is given. The aim is to simulate the nonlinear coupled motion numerically, but the nonlinear coupling causes difficulties. These difficulties are resolved by transforming to the Lagrangian represention of the fluid motion. In this representation an explicit, robust, simple numerical algorithm, based on the Störmer-Verlet method, is proposed. Numerical results of the coupled dynamics are presented. The forced motion (neglecting the coupling) leads to quite complex fluid motion, but the coupling can be a stabilising influence.
   
  H. Alemi Ardakani & T.J. Bridges. Dynamic coupling between shallow-water sloshing and horizontal vehicle motion. Euro. J. Appl. Math. 21 479-517 (2010).   Journal website  
  H. Alemi Ardakani & T.J. Bridges. Symplecticity of the Stormer-Verlet algorithm for coupling between the shallow water equations and horizontal vehicle motion. Technical Report (2010)    
 M.J. Cooker. Water waves in a suspended container, Wave Motion 20 385-395 (1994).
   
  Videos of fluid-vehicle interaction

FluidVehicle1.mpg    FluidVehicle2.mpg    FluidVehicle3.mpg    FluidVehicle4.mpg    FluidVehicle5.mpg

Parameter values associated with the above videos

Matlab codes for sloshing simulations
   
 


Link to Matlab page  


Fluid-vessel coupling for a rotating vessel
   
  The coupled liquid-vessel motion of a rotating vessel and shallow water sloshing is considered. The equations for the fluid are the rotating shallow water equations derived in Alemi Ardakani & Bridges (2009). These equations are coupled to an equation for the rotational motion of the vehicle. New equations are derived, starting with a variational formulation and the shallow-water approximation. As a test case the "pendulum slosh" problem is studied. In the pendulum slosh problem the vehicle is a pendulum with the pendulum bob containing fluid. The coupling changes the natural frequencies of the rigid body pendulum and the fluid motion in a fixed vessel. Numerical simlulations are reported.
   
 H. Alemi Ardakani & T.J. Bridges. Dynamic coupling between shallow-water sloshing and a vehicle undergoing planar rigid-body rotation, Technical Report (2010)  

The Euler equations relative to a moving frame
   
  In this technical report the details of the construction of the apparent accelerations, which appear in the Euler equations when viewed from a body fixed 3D moving frame, are presented. A moving frame has been widely used in the study of sloshing. However, there are small subtleties that have been overlooked in previous derivations, and therefore a detailed derivation is presented here.
   
 H. Alemi Ardakani & T.J. Bridges. The Euler equations in fluid mechanics relative to a rotating-translating reference frame, Technical Report (2010)  

Review of Dillingham, Falzarano & Pantazopoulos SWEs
   
  Two derivations of the shallow water equations (SWEs) for fluid in a vessel that is undergoing a general rigid-body motion in three dimensions first appeared in the literature at about the same time, given independently by Pantazopoulos (1987,1988) and Dillingham & Falzarano (1986). However both derivations follow the same strategy. Their respective derivations are an extension of the formulation for two-dimensional shallow water flow in a rotating frame in Dillingham (1981). Their idea is to start with the classical SWEs; then deduce the apparent accelerations of the body frame relative to an inertial frame. Then the gravitational force is replaced by an average of the vertical accelerations and approximations for horizontal accelerations are subsituted into the right-hand side of the horizontal momentum SWEs. The purpose of this report is to determine the precise approximations used in the derivation in order to compare with the new shallow-water equations found in Alemi Ardakani & Bridges (2009).
   
  H. Alemi Ardakani & T.J. Bridges. Review of the Dillingham, Falzarano & Pantazopoulos three-dimensional shallow-water equations. Department of Mathematics Report (2009)    
  J.T. Dillingham & J.M. Falzarano. Three-dimensional numerical simulation of green water on deck, Third International Conference on the Stability of Ships and Ocean Vehicles. Gdansk, Poland (1986).
  M.S. Pantazopoulos. Three-dimensional sloshing of water on decks, Marine Technology 25 253-261 (1988).
  M.S. Pantazopoulos. Numerical solution of the general shallow water sloshing problem, PhD Thesis: University of Washington, Seattle (1987).

Review of Huang-Hsiung rotating SWEs
   
  In the literature there are two strategies for deriving the shallow water equations (SWEs) relative to a rotating frame in three dimensions. The first -- the strategy of Dillingham, Falzarano & Pantazopoulos -- is reviewed in the report cited above. The second strategy is that of Huang & Hsiung (1996). In this report their derivation is reviewed identifying the key assumptions. The Huang-Hsiung derivation is then contrasted with a new third strategy for deriving SWEs using the surface equations derived in Alemi Ardakani & Bridges (2009).
   
  H. Alemi Ardakani & T.J. Bridges. Review of the Huang-Hsiung three-dimensional shallow-water equations. Department of Mathematics Report (2009)    
  H. Alemi Ardakani & T.J. Bridges. Review of the Huang-Hsiung two-dimensional shallow-water equations. Department of Mathematics Report (2009)    
  Z. Huang & C.C. Hsiung. Nonlinear shallow-water flow on deck, J. Ship Research 40 303-315 (1996).
  Z. Huang. Nonlinear shallow-water flow on deck and its effect on ship motion, PhD Thesis, Technical University of Novia Scotia (1995).

Other technical reports on shallow water sloshing
   
  H. Alemi Ardakani & T.J. Bridges. Asymptotics of (SWE-1) and (SWE-2) in the shallow water limit in three dimensions. Department of Mathematics Report (2010)    
   
  H. Alemi Ardakani & T.J. Bridges. Shallow water sloshing in rotating vessels: details of the numerical algorithm. Department of Mathematics Report (2009)    
   
 H. Alemi Ardakani & T.J. Bridges. Review of the Armenio-LaRocca two-dimensional shallow-water equations, Department of Mathematics Report (2009)    
   
 H. Alemi Ardakani & T.J. Bridges. Yaw forcing with the vessel position also plotted -- towards a video of 3D sloshing, Department of Mathematics Report (2009)    
   
 H. Alemi Ardakani & T.J. Bridges. Coupled roll-pitch motions: 1:2 resonance simulations, Department of Mathematics Report (2010)    
   
 H. Alemi Ardakani & T.J. Bridges. Review of the 3-2-1 Euler angles: a yaw-pitch-roll sequence, Department of Mathematics Report (2010)    
   
 H. Alemi Ardakani & T.J. Bridges. Surge-sway simulations with additional detail, Department of Mathematics Report (2010)     The size of this file is almost 20 Mb, so it has been gzip-ed down to less than 1 Mb. To decompress it in a unix/linux environment just type gunzip and the file name and it will convert it back to .pdf file.

Compendium of references on shallow water sloshing 
   

  Department of Mathematics     University of Surrey