Numerical modelling of forces, stresses and breakages of concrete armour units
John Paul Latham (Imperial College London)
Jiansheng Xiang (Imperial College London)
Elena Anastasaki (Imperial College London)
Liwei Guo (Imperial College London)
Nikolaos Karantzoulis (Imperial College London)
Axelle Vire (TU Delft - Wind Energy)
Christopher Pain (Imperial College London)
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Abstract
Numerical modelling has the potential to probe the complexity of the interacting physics of rubble mound armour systems. Through forward modelling of armour unit packs, stochastic variables such as unit displacement and maximum contact force per unit during an external oscillatory disturbance can be predicted. The combined finite-discrete element method (FEMDEM) is a multi-body method ideally suited to model the behaviour of the armour layer system and the stresses generated within complex shape units. In this paper we highlight the latest developments made with the application of FEMDEM technology to breakwater modelling including realistic rock underlayer and concrete unit layer topologies, maximum contact force distributions, internal unit stresses, fracture and unit breakages. Finally, fully coupled wave and multi-body armour unit motion with internal dynamic stress generation is illustrated.