In this study, comparative analysis has been performed with regard to a bending stress and deformation at bottom slab of a concrete floating container terminal by live load distributions. In addition, a structural performance and behavior of the floating structure is considered using a numerical analysis. Through reviewed structural performance of a floating structure by live load distribution, the structure presented tensile behavior by two live load cases (A, B, D-type). Then, the other live load cases (C, E, F, G, H, I, J-type) shows compressive behavior. Especially, immoderately compressive stress was generated on bottom slab at specific load distribution. but, that should be decreased through controling buoyancy pre-flexion. Through reviewed structural behavior, slopes of structure by four live load cases (B, E, F, H-type) were exceeded in design criteria of mega-float. It should be estimated that it get out of the load case at loading container. In all, the present study can be considered as a benchmark of a floating container terminal in the absence of analysis and will be used to guide-line about serviceability of concrete floating container terminal.

Using the wave forces obtained from ANSYS AQWA, the structural analysis of the gravity substructure for 5MW offshore wind turbines is carried out through ANSY Mechanical. Moreover, the comparison of natural frequency between the wind turbine and the gravity substructure is made to investigate the resonance. It is found that the suggested gravity substructure can be an effective substructure for 5MW offshore wind turbines.

Recently, research have been rapidly increased for performance of offshore wind turbine. In this study, static structural analysis was carried out for a structural performance of hybrid concrete sub-structure of offshore wind turbine under environmental loads.

Blades of wind farm structures should be designed to maximize the capacity generating lift force in the specific range of wind velocity. Although many studies related to wind farm efficiency have been performed but it is few to secure safety in the environment of high wind velocity. This study uses Computational Fluid Dynamics to analyze wind load on the blade and member force transferred to footing. And it is analyze wind load property variation related to the turbulence intensity because the wind property variation can be affected to generate the unstable motion on the blade, tower and footing. The maximum force loaded on the footing can be affected to the response of structure. The load variation by turbulence intensity can be considered when design the wind farm structures.

In this study, an analytical studies were carried out for the buoyancy preflexion method to improve structural performance of concrete floating structures. The buoyancy preflexion means that the preflexion effects were induced to the floating structure due to the difference in buoyancy between the pontoon modules composing the floating structures. As the results of this study, it was found that the buoyancy preflexion significantly influence on structural performance of floating structures.