Adaptive breakwaters with inflatable elements for coastal protection. Preliminary numerical estimation of their performance.

Excessive erosion of sand beaches defines a serious problem worldwide and is particularly pronounced in the Mediterranean region. One of the typical measures for alleviating this erosion consists in building rigid breakwaters in the vicinity of the coast for diminishing sand transport. This solution, however, is often accompanied by undesirable alteration of the coastline. In this work we address the viability of using conceptually new structures with inflatable elements striving to improve the control over the sediment transport. The aim of the inflatable element is to adapt the breakwater configuration to the sea state. A preliminary design is proposed and tested in a number of storm scenarios using an in-house finite element/level set model. Influence of various breakwater design parameters upon its functionality is studied. Transmission coefficients and maximum pressures exerted upon the breakwater are estimated. Numerical study performed shows that for the considered range of storm scenarios the proposed design is characterized by transmission coefficients below 0.5. It is also shown that the use of inflatable elements facilitates adaptation of the breakwater functionality to a given sea state. • An adaptive breakwater: inflatable tubes on top of an immersed rigid platform. • Performance studied via in-house enhanced FEM/level-set model. • Transmission coefficients and flow characteristics estimated for various storm scenarios. • Design parameters' influence upon efficiency of the breakwater studied. • Breakwater's ability of adapting to storm conditions shown. [ABSTRACT FROM AUTHOR]