A floating concrete pontoon is at high risk for damage and fatigue because of exposure to the marine environment loads. In this study, the dynamic properties of the structure are extracted by field test, and the stiffness of the structure is estimated through a system identification method. In addition, the stress distribution of the structure is determined by the wave loads, and the fatigue damage induced by each wave load are calculated using the estimated stiffness and DNV-code based S-N curve.

The purpose of this study is to estimate structural integrity evaluation of the concrete pontoon structure when the boundary condition and time changes. The structural integrity evaluation is conducted through the system identification method using dynamic properties. Dynamic properties are extracted with the structures when it is located on the ground and submerged in the sea. The variation of the structural stiffness due to a certain period time is discussed.

In this study, we evaluated the long-term properties of long-tern pontoon concrete which has excellent mechanical properties and CO2 reduction effect. The low-carbon pontoon concrete was substituted unit weight of cement partly with ground granulated blast furnace slag to secure the durability and eco-friendly. As a result, the low-carbon pontoon concrete was better long-term properties than plain concrete.

본 연구에서는 수상위에 진수된 콘크리트 플로팅 폰툰에 상부골조를 단계별로 시공함에 따라 발생하는 추가 처짐이 상부골조에 발생하므로 추가변형에 의한 상부골조의 추가 모멘트량을 산정하는 해석절차를 제시하였으며 제시된 절차에 따라 3층 예제 철골 건물을 해석하고 분석하였다. 제시된 시공단계를 고려한 해석 방법과 비교하여, 폰툰의 변형을 고려하지 않는 해석 방법은 수직하중에 의한 변형을 무시하여 설계하중을 과소평가 하며, 플로팅 구조물을 전 층을 모델링하고 하중을 동시에 작용시키는 모델은 과대 처짐의 영향으로 설계하중을 과대평가함을 알게 되었다.