Delft3D Flexible Mesh – Coastal Morphodynamic Modelling

This course focuses on estuarine, coastal and marine processes as well as the resulting morphological features and their morphodynamic behavior at various time scales.

The course starts with wave dynamics. To simulate the evolution of random, short-crested wind generated waves in coastal waters (which may include estuaries, tidal inlets, barrier islands with tidal flats, channels etc.) the new wave module D-Waves of the Delft3D FM Suite is designed. This wave module computes wave propagation, wave generation by wind, non-linear wave-wave interactions and dissipation, for a given bottom topography, wind field, water level and current field in waters of deep, intermediate and finite depth.

The second part of the course focuses on morphodynamic modelling. The D-Morphology module of the Delft3D FM Suite integrates the effects of waves, currents, sediment transport on morphological development, related to sediment sizes ranging from silt to gravel. It is designed to simulate the morphodynamic behavior of rivers, estuaries and coasts on time-scales of days to years. The typical problems to be studied using the morphological module involve complex interactions between waves, currents, sediment transport and bathymetry. To allow such interactions, the individual modules within Delft3D FM Suite all interact through a well-defined common interface.

In this course, presentations, hand-on case study and papers are used to develop skills in analyzing and solving morphodynamic problems.

Some areas of applications are

  • The D-Waves module can optionally be coupled with the other modules of the Delft3D FM Suite. In this way an efficient and direct coupling is obtained between e.g. the D-Flow FM module (wave driven currents) and the D-Morphology module (stirred by wave breaking);
  • Coastal areas including beaches, channels, sand bars, harbour moles, offshore breakwaters, groynes and other structures. The coastal areas may be intersected by tidal inlets or rivers, parts of it may be drying and flooding;
  • Rivers including bars, river bends (spiralflow effect), bifurcations, non-erodible layers, dredging operations and having arbitrary cross-sections (with overbankflow). Various structures may be included;
  • Estuaries including tidal inlets and river deltas influenced by tidal currents, river discharges and density currents due to sediment. Sediment can be non-cohesive (sand) or cohesive (silt). The areas may include drying and flooding, channels and man-made structures, e.g. docks, jetties and land reclamations.

Objective of the course

Participants will learn:

  • A basic theoretical understanding of Delft3D FM morphology capabilities and functionalities.
  • Knowledge on how to apply the software for research or consultancy studies.

Course subjects

  • Introduction on wave prediction in coastal areas and wave models;
  • D-Waves module (SWAN engine) as used in the Delft3D FM Suite;
  • Introduction on steering the different processes;
  • Setting up and running wave simulation;
  • D-Morphology module as used in the Delft3D FM Suite;
  • Setting up and running wave-current interaction simulation;
  • Setting up and running morphology simulation;
  • Setting up and running wave-current-morphology simulation for coastal areas or rivers.

This course is aimed at

Project engineers, project leaders, consultants, and researchers.

Prerequisite knowledge:

  • Basic Hydrodynamic
  • Coastal Hydrodynamics course – A Delft3D Flexible Mesh training in Coastal Hydrodynamics

Online Course dates

Session 1: Monday, 4 April 2021, 09:00 – 13:00 CEST (Delft time, UTC+2)
Session 2: Tuesday, 5 April  2021, 09:00 – 13:00 CEST
Session 3: Wednesday,  6 April 2021, 09:00 – 13:00 CEST
Session 4: Thursday, 7 April 2021, 09:00 – 13:00 CEST

Fee

The registration fee for this course is € 1.450, – excluding VAT.

50% discount for lecturers at centers of education.

Register