Abstract:

The sea structures can be designed fixed on the base or swimming. Today, the use of swimming structures is rapidly increasing due to their service in every depth. These structures allow the pontons on the base to swim. In this study, two different pontons produced from different materials were performed a numerical analysis of the influence of wave forces. The first (Model 1) of the structures is designed to be a non-contained concrete inside dust. The second structure is designed using hard plastic materials. In the analysis, the Abaqus final elements program was used. The interaction between the structure and the sea environment in which it is located is carried out by double-directional fluid-building interaction analysis. The dual-directional interaction analysis has been modeled with the combination of Eulerian-Lagrangian approaches (CEL). In interactive modeling, no surface has been defined, unlike other modeling techniques. Interaction is only carried out by defining general contact characteristics. This type of modeling (CEL) uses only the Abaqus/Explicit solution. The sea environment is Eulerian, and the structure is modeled by the Lagrangian approach. In the modeling of the sea environment, the linear wave speed profile was used. Sensitivity analyses have been performed to determine the most suitable points and the number of elements. Sensitivity analysis is performed through modal behavior. Numeric model's curved wave is made through water face profiles. Water face profiles that change over time have been obtained analytically and numerically at two different points. The conformity of the analytical and numerical wave profiles has been identified numerically and visually. In the structural analysis, modal behaviors, frequencies and distribution of retreat were obtained. At the end of the study, the numbers of points and elements to be used in the event of the use of a different fluid-building interaction technique were obtained. The effect of these values on solving is discussed in terms of time and memory requirement.

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