직립방파제의 케이슨 활동에 대한 최초통과확률법의 허용기준 산정

Abstract

Probabilistic design methods can consider uncertainties of design variables and are widely used in the design of vertical breakwaters. The probabilistic design methods include a partial safety factor method, reliability-based design method, and performance-based design method. Especially the performance-based design method calculates the accumulated sliding distance during the lifetime of the breakwater or during a design storm. Recently a time-dependent performance-based design method has been developed based on the first-passage probability of individual sliding distance during a design storm. However, because the allowable criteria in the first-passage probability method are not established, the stability of structures cannot be quantitatively evaluated. In this study, the allowable first-passage probabilities for two limit states are proposed by calculating the first-passage probabilities for the cross-sections designed with various water depths and characteristics of extreme wave height distributions. The allowable first-passage probabilities are proposed as 5% and 1%, respectively, for the repairable limit state (allowable individual sliding distance of 0.03 m) and ultimate limit state (allowable individual sliding distance of 0.1 m). The proposed criteria are applied to the evaluation of the effect of wave-height increase due to climate change on the stability of the breakwater. 핵심용어: vertical breakwater, first-passage probability method, allowable first-passage probability, probabilistic design method, ì§ë¦½ë°©íŒŒì œ, ìµœì´ˆí†µê³¼í™•ë¥ ë²•, í—ˆìš©ìµœì´ˆí†µê³¼í™•ë¥ , í™•ë¥ ë¡ ì  설계법