This study is a part of the research on the development of safety monitoring system and monitoring program of 3MW offshore wind support structure using fiber optic sensor. In this paper, we propose a maintenance system for offshore wind support structure using fiber optic sensor based on the analysis of current monitoring status and related standards of domestic and overseas offshore wind support jacket structures.

In this research, we carried out design and analysis with joint of concrete supporting structure for offshore wind energy. We developed load transfer mechanism about applied load induced from steel tower to concrete foundation. Also, a commercially available finite element program, ABAQUS 6.10, is used to analyze behavior of structure.

In this research, we used half model instead of full model in order to consider convergence and analysis running time. We carried out nonlinear analysis on the joints between steel tower to concrete supporting structure of the 5MW offshore wind turbine applying only half of the load on the joint.

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.

This study investigated the effect of cement type and ground granulated blast furnace slag (GGBS) on the mechanical properties and workability of grout for offshore PSC structures. As the replacement ratio of GGBS increased, the flowability of the grout increased and both intial and final setting times of grout was delayed regardless of cement type. However, the effects of GGBS on the bleeding of grout were different according to the type of cement: as the ratio of GGBS increased, less bleeding was observed for the grout with typeⅠ cement whereas higher bleeding was generated for the grout with type Ⅲ cement. However, there was no significant difference in their compressive strength at 28 day according the different replacement ratio of GGBS from 0 to 40%.

레이더 리프렉터를 소형어선, 어망 부이, 어업용 바지선 등에 장착할 경우 최적설치 위치를 결정하기 위한 최적화 시스템의 개발이 필요하다. 최적화 시스템을 개발하기 위한 기본 단계로써 소형어선, 어망 부이, 어업용 바지선 등이 파랑에 의하여 어떠한 응답 특성을 나타내는지 정확하게 파악해야 한다. 본 논문에서는 먼저 해양 부유체식 어업용 바지선 구조물을 대상으로 파랑에 의한 거동을 해석하고자 한다. 어업용 바지선 구조물의 파랑 중 응답특성을 파악하기 위하여 각종 영향인자, 즉 파의 길이, 수심, 입사하는 파의 방향 등이 바지선의 응답에 미치는 영향에 대하여 검토한다. 이러한 응답 특성을 토대로 어업용 레이더 리프렉터를 바지선이나 소형 선박에 설치하였을 경우 파랑에 의한 영향이 레이더 반사 면적에 어떠한 영향을 미치는지를 파악하는 기초자료로 사용하고자 한다.

우리나라가 세계 물류기지의 중심 국으로 발전하기 위해서는 날로 급증하고 있는 물류량을 처리하기 위한 항만의 건성이 시급한 과제이다. 국토가 좁고 대도기에 인구가 급증하고 있으나 삼면이 바라도 둘러 쌓여 잇는 우리나라의 경우에는 해양공간개발이 필요하다. 증가하는 물류량은 처리할 수 있는 항만의 건설을 위하여 본 연구에서는 초대형 부유채식 컨테이너 야드를 제안하고 해상에 설치되는 초대형 부유채식 컨테이너 야드가 파의 길이 , 해역의 수심, 입사하는 파의 방향등에 따라서 어떠한 응답특성을 나타내는지 파악한다.

A numerical model for practical use based on the 1-line theory is presented to simulate shoreline changes due to construction of offshore structures. The shoreline change model calculates the longshore sediment transport rate using breaking waves. Before the shoreline change model execution, a wave model, adopting the modified Boussinesq equation including the breaking parameters and bottom friction term, was used to provide the longshore distribution of the breaking waves. The contents of present model are outlined first. Then to examine the characteristics of this model, the effects of the parameters contained in this model are clarified through the calculations of shoreline changes for simple cases. Finally, as the guides for practical application of this model, several comments are made on the parameters used in the model, such as transport parameter, average beach slope, breaking height variation alongshore, depth of closure, etc. with the presentation of typical examples of 3-dimensional movable bed experimental results for application of this model. Here, beach change behind the offshore structures is represented by the movement of the shoreline position. Analysis gives that the transport parameters should be taken as site specific parameters in terms of time scale for the shoreline change and adjusted to achieve the best agreement between the calculated and the observed near the structures.

In the country where the population concentrates in the metropolis with the narrow land, development of the ocean space is necessary. Recently, mega-float offshore structure has been studied as one of the effective utilization of the ocean space. And very large floating structures are now being considered for various applications such as floating airports, offshore cities and so on. This very large structure is relatively flexible compared with real floating structures like large ships. when we estimate dynamic responses of these structures in waves, the elastic deformation is important, because vertical dimension is small compared with horizontal. And it is necessary to examine the effect of ocean wave external force received from the natural environment. In this study, the mat-type large floating structure is made to be analytical model. And the analysis of the dynamic response as it receives regular wave is studied. The finite element method is used in the analysis of structural section of this model. And the analysis is carried out using the boundary element method in the fluid division. The validity of analysis method is verified in comparison with the experimental result in the Japan Ministry of Transport Ship Research Institution. In order to know the characteristics of the dynamic response of the large floating structures, effects of wavelength, bending rigidity of the structure, water depth, and wave direction on dynamic response of the floating structure are studied by use of numerical calculation.