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Part-I … Comparative Study and Improvement in Shallow Water Model

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1 Part-I … Comparative Study and Improvement in Shallow Water Model
Dr. Rajendra K. Ray Assistant Professor, School of Basic Sciences, Indian Institute of Technology Mandi, Mandi , H.P., India Collaborators: Prof. Kim Dan Nguyen & Dr. Yu-e Shi Speaker: Dr. Rajendra K. Ray Date:

2 Outlines Introduction Governing Equations and projection method
Wetting and drying treatment Numerical Validation Parabolic Bowl Application to Malpasset dam-break problem Conclusion Dr. Rajendra K. Ray

3 Introduction Free-surface water flows occur in many real life flow
situations Many of these flows involve irregular flow domains with moving boundaries These types of flow behaviours can be modelled mathematically by Shallow-Water Equations (SWE) The unstructured finite-volume methods (UFVMs) not only ensure local mass conservation but also the best possible fitting of computing meshes into the studied domain boundaries The present work extends the unstructured finite volumes method for moving boundary problems Dr. Rajendra K. Ray

4 Governing Equations and projection method
Shallow Water Equations: Continuity Equation Momentam Equations Dr. Rajendra K. Ray

5 Governing Equations and projection method …
Convection-diffusion step Wave propagation step Dr. Rajendra K. Ray

6 Governing Equations and projection method …
Velocity correction step Equations (4)-(8) have been integrated by a technique based on Green’s theorem and then discretised by an Unstructured Finite-Volume Method (UFVM). The convection terms are handled by a 2nd order Upwind Least Square Scheme (ULSS) along with the Local Extremum Diminishing (LED) technique to preserve the monotonicity of the scalar veriable The linear equation system issued from the wave propagation step is implicitly solved by a Successive Over Relaxation (SOR) technique. Dr. Rajendra K. Ray

7 Steady wetting/drying fronts over adverse steep slopes in real and discrete representations
Dr. Rajendra K. Ray

8 Modification of the bed slope in steady wetting/drying fronts over adverse steep slopes in real and discrete representations Dr. Rajendra K. Ray

9 Wetting and drying treatment
The main idea is to find out the partially drying or flooding cells in each time step and then add or subtract hypothetical fluid mass to fill the cell or to make the cell totally dry respectively, and then subtract or add the same amount of fluid mass to the neighbouring wet cells in the computational domain [Brufau et. al. (2002)]. To consider a cell to be wet or dry in an particular time step, we use the threshold value as the minimum water depth (h) If the cell will be considered as dry and the water depth for that cell set to be fixed as for that time step Dr. Rajendra K. Ray

10 Conservative Property
Definition: If a numerical scheme can produce the exact solution to the still water case: then the scheme is said to satisfy the Conservative Property (C-property) [Bermudez and Vázquez 1994]. Proposition 1. The present numerical scheme satisfies the C-property. Proof. The details of the proof can be found in Shi et at (Comp & Fluids). Dr. Rajendra K. Ray

11 Numerical Validation Parabolic Bowl :
To test the capacity of the present model in describing the wetting and drying transition The bed topography of the domain is defined by , where is a positive constant and The water depth is non-zero for The analytical solution is periodic in time with a period The analytical solution is given within the range as Dr. Rajendra K. Ray

12 Numerical Validation …
Parabolic Bowl … For computation purpose, , and are fixed as , and respectively The computational domain ( ) is considered as a square region with the origin at the domain centre The threshold value is set as Dr. Rajendra K. Ray

13 Numerical Validation …
Parabolic Bowl … Dr. Rajendra K. Ray

14 Numerical Validation …
Parabolic Bowl … Dr. Rajendra K. Ray

15 Numerical Validation …
Parabolic Bowl … Mesh size Rate [13X13] 1.478 1.377 1.410 [25X25] 1.412 1.354 1.363 [50X50] 1.409 1.407 1.425 [100X100] 1.403 1.413 1.397 [200X200] Mesh size Rate [13X13] 1.143 1.378 1.384 [25X25] 1.416 1.181 1.182 [50X50] 1.410 1.346 1.365 [100X100] 1.403 1.396 1.401 [200X200] Dr. Rajendra K. Ray

16 Numerical Validation …
Parabolic Bowl … Average Rate of convergence Bunya et. al. (2009) 1.33 0.84 Ern et. al. (2008) 1.4 0.5 Present Relative error in global mass conservation is less than 0.003% Dr. Rajendra K. Ray

17 Application to the Dam-Break of Malpasset
Back Grounds The Malpasset Dam was located at a narrow gorge of the Reyran River valley (French Riviera) with water storage of It was explosively broken at 9:14 p.m. on December 2, 1959 following an exceptionally heavy rain The flood water level rose to a level as high as 20 m above the original bed level The generated flood wave swept across the downstream part of Reyran valley modifying its morphology and destroying civil works such as bridges and a portion of the highway After this accident, a field survey was done by the local police In addition, a physical model was built to study the dam-break flow in 1964 Dr. Rajendra K. Ray

18 Application to the Dam-Break of Malpasset …
Available Data The propagation times of the flood wave are known from the exact shutdown time of three electric transformers The maximum water levels on both the left and right banks are known from a police survey The maximum water level and wave arrival time at 9 gauges were measured from a physical model, built by Laboratoire National d’Hydraulique (LNH) of EDF in 1964 Dr. Rajendra K. Ray

19 Application to the Dam-Break of Malpasset …
Results and Discussions Water depth and velocity field at t =1000 s Water depth at t =2400 s, wave front reaching sea Dr. Rajendra K. Ray

20 Application to the Dam-Break of Malpasset …
Results and Discussions … Table 5. Shutdown time of electric transformers (in seconds). Electric Transformers A B C Field data 100 1240 1420 Valiani et al (2002) 98 -2% 1305 5% 1401 -1% TELEMAC 111 11% 1287 4% 1436 1% Present model 85 -15% 1230 1396 Dr. Rajendra K. Ray

21 Application to the Dam-Break of Malpasset …
Results and Discussions Profile of maximum water levels at surveyed points located on the right bank Arrival time of the wave front Dr. Rajendra K. Ray

22 Application to the Dam-Break of Malpasset …
Results and Discussions maximum water levels at surveyed points located on the left bank Maximum water level Dr. Rajendra K. Ray

23 Dr. Rajendra K. Ray

24 Conclusions We extended the unstructured finite volume scheme for the wetting and drying problems This extended method correctly conserve the total mass and satisfy the C-property Present scheme very efficiently capture the wetting-drying-wetting transitions of parabolic bowl-problem and shows almost 1.4 order of accuracy for both the wetting and drying stages Present scheme then applied to the Malpasset dam-break case; satisfactory agreements are obtained through the comparisons with existing exact data, experimental data and other numerical studies The numerical experience shows that friction has a strong influence on wave arrival times but doesn’t affect maximum water levels Dr. Rajendra K. Ray

25 References Dr. Rajendra K. Ray 16.09.2014
Bermudez A., Vázquez M.E., Upwind Methods for Hyperbolic Conservation Laws with Source Terms. Comput. Fluids, 23, p. 1049–1071. Brufau P., Vázquez-Cendón M.E., García-Navarro, P., A Numerical Model for the Flooding and Drying of Irregular Domains. Int. J. Numer. Meth. Fluids, 39, p. 247–275. Ern A., Piperno S., Djadel K., A well-balanced Runge–Kutta discontinuous Galerkin method for the shallow-water equations with flooding and drying. Int. J. Numer. Meth. Fluids, 58, p. 1–25. Hervouet J.M., Hydrodynamics of free surface flows-Modelling with the finite element method, John Willey & sons, ISBN , 341 p. Nguyen K.D., Shi Y., Wang S.S.Y., Nguyen T.H., D Shallow-Water Model Using Unstructured Finite-Volumes Methods. J. Hydr Engrg., ASCE, 132(3), p. 258–269 . Shi Y., Ray R. K., Nguyen K.D., A projection method-based model with the exact C-property for shallow-water flows over dry and irregular bottom using unstructured finite-volume technique. Comput. Fluids, 76, p. 178–195. Technical Report HE-43/97/016A, Electricité de France, Département Laboratoire National d’Hydraulique, groupe Hydraulique Fluviale. Valiani A., Caleffi V., Zanni A., Case study: Malpasset dam-break simulation using a two-dimensional finite volume method. J. Hydraul. Eng., 128(5), 460–472. Dr. Rajendra K. Ray

26 Collaborators: Prof. K. D. Nguyen, Dr. D. Pham Van Bang & Dr. F. Levy
Part-II … Two-Phase modelling of sediment transport in the Gironde Estuary (France) Dr. Rajendra K. Ray Assistant Professor, School of Basic Sciences, Indian Institute of Technology Mandi, Mandi , H.P., India Collaborators: Prof. K. D. Nguyen, Dr. D. Pham Van Bang & Dr. F. Levy Speaker: Dr. Rajendra K. Ray Date:

27 Physical oceanography of the Gironde estuary
Confluence of the GARONNE and DORDOGNE: 70km to the mouth Width: 2km - 14km Average depth : 7-10m 2 main channels : NAVIGATION & SAINTONGE Partially mixed and macro-tidal estuary Amplitude : 1,5-5m Averaged river discharge ( ) : 760 m3/s Solid discharge ( ): 2,17 million tons/year 27

28 Body fitted mesh for Dordogne river
River Discharge Free Water Surface Imposed

29 Body fitted mesh for Garonne river
River Discharge Free Water Surface Imposed

30 Body fitted mesh for Gironde Estuiry
Free Water Surface Imposed (tidal) Free Water Surface Imposed (node)

31 PALM coupling for Gironde Estuary

32 Results and Discussions

33 Results and Discussions

34 Thank you Dr. Rajendra K. Ray


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