Presentation is loading. Please wait.

Presentation is loading. Please wait.

Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of.

Published byLaurence Shields Modified over 9 years ago

Similar presentations

Presentation on theme: "Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of."— Presentation transcript:

1 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Sediment Transport Modelling Belgian part of the North Sea Dries Van den Eynde, Michael Fettweis, Fritz Francken, Vera Van Lancker Management Unit of the North Sea Mathematical Models Jaak Monbaliu, Erik Toorman Katholieke Universiteit Leuven Job Janssens, Joris Vanlede, Toon Verwaest Flanders Hydraulics Research

2 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Overview  Two sediment transport models –Transport of material in suspension MU-STM –Transport of sand MU-SEDIM  New developments –Bottom model –Flocculation model  Conclusions

3 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Sediment transport model mu-STM  Semi-Lagrangian model – based on Second Moment Method  Bottom stress under influence of currents and waves  Erosion and sedimentation  Consolidation model with different layers in the bottom  Boundary conditions  Applications –Dispersion of dumped material – optimisation of dredging works –Sediment balance for the Belgian Continental Shelf  Turbidity maximum is a natural phenomenon not caused by the dumping  Most of the material that enters the BCS from the Dover Strait, disappears to the North

4 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Sediment transport model MU-SEDIM  Bottom stress as function of currents and waves: Bijker formula  Bottom roughness –Skin-friction, roughness by bottom load, roughness by bottom ripples  Shields-criterium for start of sediment transport  Different formulae for local total load –Ackers-White (1973) with adaptations of Swart (1976, 1977) –  many different formulae available, results vary of orders of magnitude  Continuity for bottom: erosion and sedimentation  Applications –Modelling of volumetric changes of Kwintebank, assess effects of sand extraction –Modelling sediment transport at wind mill farms

5 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Q4D Sediment transport model MU-STM MU-SEDIM Multi-classes Flocculation model Bed model Geological information Armouring Sand/mud layers

6 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Fall velocity of flocs  p : density of primary particles  grain size analysis, OM, CaCO3 of SPM sample (2580 kg/m³)  w : density of water  CT measurements D f : floc size  LISST measurements D p : primary particle size  grain size analysis of SPM sample (1.8 µm - 7.2 µm)  : molecular viscosity g : gravitation constant  f : density of flocs nf : fractal dimension ,  : parameters of sphericity of flocs Re : floc Reynolds number Stokes law Flocs with fractal structure (Winterwerp, 1998)

7 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Flocculation models (settling velocity) Kwintebank: 2-11 March 2004

8 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Bioflocculation model Maggi  Calculates floc formation and breakup under influence of turbulence, SPM, primary particle size, fractal dimension, organic fraction, biomass growth

9 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Result 1D

10 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Result 1D

11 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Towards 2D model  Definition of the parameters over the BCP –Organic content –Other parameters

12 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Result 2D

13 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Geology - Tertiary and Quarternary clay Compact cohesive sediments in first m Fettweis et al. 2007. Mud origin, characterisation and human activities (MOCHA). Belgian Science Policy.

14 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/

15 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Biological activity and sediment erosion/stabilization Ensis directus (American jackknife clam) at Koksijde after a storm Invasive species Lives in great numbers and high densities in sandy substratum. Can be released due to extreme events (storm) Empty shells in high densities can form “reef” structures. Spatial extent of Ensis beds will be available by autumn ’09: Belgian Science Policy project ‘Ensis’ (2009-2011) Photo F. Kerkhof

16 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Critical erosion shear stress measurements Very soft consolidated mud (navigation channel) Critical shear stress measurement: 0.5-4Pa (top), 4-9 Pa (rest) Bulk density: 1.3-1.6 g/cm³ (carried out by Westrich & Jancke, Stuttgart Univ.) Fluid mud on top, sandy with shell fragments; very soft mud with intercalation of sand layers

17 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Bed model: parent bed – active bed In order to incorporate erosion of old sediments the bed is split in active & parent part Active layer: consist of different sub-layers to allow consolidation of mud, pore filling of sand by mud and segregation between sand/mud layers Cohesive sediments (fine, mixed) Active bed layers :  ce < 4 Pa, sedimentation/erosion processes, corresponds to recent sediments Parent bed layer :  ce > 4 Pa, only erosion processes, corresponds to old sediments (Holocene, tertiary clays near surface) Sandy sediments active & passive layers

18 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Bed model - variables Erosion characteristics:  ce at surface  ce averaged over the depth interval Density averaged over the depth interval Mass over the depth interval Critical erosion rate averaged over the depth interval  Maps are constructed based on geological constraints and erosion flume experiments Recent mud  ce <4Pa Compact mud  ce > 4Pa

19 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Bed model - variables Sediment characteristics: 8 grain size classes from gravel to clay Clay is defined as fraction <8 µm is based on the difference between sortable silts and aggregated particles (Chang et al., 2007) Cohesive – non cohesive behaviour is based on Van Ledden et al. (2004) adapted according to clay definition  Maps are constructed based on sedimentological data

20 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Bed model - ternary diagram Most sediments fall into I : non cohesive sand dominated II : cohesive mixed sediments III : non-cohesive mixed sediments IV : cohesive clay dominated Van Ledden et al. (2004)

21 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Bed model cohesive/non cohesive

22 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/ Conclusions  Flocculation model gives good predictions of the floc size  Dependent on geographical distribution of parameters like fractal dimension, …  Bed model: active and parent bed  Geological, sedimentological and erosion behaviour are included  Biological data: more data will become available  Further work: model simulations –Armouring –Different layers of sand / mud

23 Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of the North Sea Mathematical Models MUMM | BMM | UGMM http://www.mumm.ac.be/

Download ppt "Quest4D Workshop Sediment Dynamics and Increasing Anthropogenic Pressure: Ways Forward? Flanders Hydraulics Research, May 14 th, 2009 Management Unit of."

Similar presentations

1B Clastic Sediments Lecture 27 SEDIMENT TRANSPORT Onset of motion

1B Clastic Sediments Lecture 27 SEDIMENT TRANSPORT Onset of motion
Hydrodynamics and Sediment Transport Modelling Ramiro Neves

Hydrodynamics and Sediment Transport Modelling Ramiro Neves
CLASTIC TRANSPORT AND FLUID FLOW

CLASTIC TRANSPORT AND FLUID FLOW
Irene Seco Manuel Gómez Alma Schellart Simon Tait Erosion resistance and behaviour of highly organic in-sewer sediment 7th International Conference on.

Irene Seco Manuel Gómez Alma Schellart Simon Tait Erosion resistance and behaviour of highly organic in-sewer sediment 7th International Conference on.
GE0-3112 Sedimentary processes and products Lecture 4. Sedimentary structures II – sediment massive flows Geoff Corner Department of Geology University.

GE Sedimentary processes and products Lecture 4. Sedimentary structures II – sediment massive flows Geoff Corner Department of Geology University.
JSSBIO1Huttula Lecture Set 41 5. Sediment transport models.

JSSBIO1Huttula Lecture Set Sediment transport models.
First steps in the implementation of a sediment transport model in the Ebro Delta Continental Shelf (Catalan Sea) UPC - LIM - Juan Fernandez, Manuel Espino,

First steps in the implementation of a sediment transport model in the Ebro Delta Continental Shelf (Catalan Sea) UPC - LIM - Juan Fernandez, Manuel Espino,
Stoke’s Law and Settling Particles

Stoke’s Law and Settling Particles
For flow of 1 m/s in round-bottom channel of radius 1 m, what is the Reynold’s number? Is the flow laminar or turbulent? Re < 500 laminar Re > 2000 turbulent.

For flow of 1 m/s in round-bottom channel of radius 1 m, what is the Reynold’s number? Is the flow laminar or turbulent? Re < 500 laminar Re > 2000 turbulent.
Marine Sedimentation. Streams Rivers Glaciers Landslide (Gravity)

Marine Sedimentation. Streams Rivers Glaciers Landslide (Gravity)
Introduction to Oceanography

Introduction to Oceanography
G. M. Cartwright, C. T. Friedrichs, and L. P. Sanford.

G. M. Cartwright, C. T. Friedrichs, and L. P. Sanford.
Sedimentary Rocks.

Sedimentary Rocks.
SEDIMENTARY ROCK Section 6.3.

SEDIMENTARY ROCK Section 6.3.
Threshold of Grain Motion 1. Definition - “general sediment movement” beyond occasional motion a. more or less continuous b. includes grains on all surfaces.

Threshold of Grain Motion 1. Definition - “general sediment movement” beyond occasional motion a. more or less continuous b. includes grains on all surfaces.
Tom T.-J. Hsu, Assistant Professor Civil & Coastal Engineering University of Florida High Resolution Numerical Modeling of Cohesive Sediment Transport.

Tom T.-J. Hsu, Assistant Professor Civil & Coastal Engineering University of Florida High Resolution Numerical Modeling of Cohesive Sediment Transport.
1 Flow, disintegration and lubrication of clay – sandy debris flows: from the laboratory to the field Anders Elverhøi Fabio De Blasio Dieter Issler Johann.

1 Flow, disintegration and lubrication of clay – sandy debris flows: from the laboratory to the field Anders Elverhøi Fabio De Blasio Dieter Issler Johann.
Sediment Movement after Dam Removal

Sediment Movement after Dam Removal
Particle Settling Velocity Put particle in a still fluid… what happens? Speed at which particle settles depends on: particle properties: D, ρ s, shape.

Particle Settling Velocity Put particle in a still fluid… what happens? Speed at which particle settles depends on: particle properties: D, ρ s, shape.
Soil Types Soil – all unconsolidated material in the earth’s crust Soil includes – Mineral particles – sand and clay Organic Materials – found in topsoil.

Soil Types Soil – all unconsolidated material in the earth’s crust Soil includes – Mineral particles – sand and clay Organic Materials – found in topsoil.

Similar presentations

Ads by Google