Plasticity and Fracture Behaviors of Marine Structural Steel, Part II: Theoretical Backgrounds of Fracture
J. Ocean Eng. Technol.. 2011;25(2):92-100. DOI: https://doi.org/10.5574/KSOE.2011.25.2.092
|
Citations to this article as recorded by
On the structural behavior of ship's shell structures due to impact loading
Hyung Kyun Lim, Joo-Sung Lee
International Journal of Naval Architecture and Oc.2018; 10(1): 103. CrossRef
On the Derivation of Material Constants Associated with Dynamic Behavior of Heat Formed Plates
Lee Joo-Sung, Lim Hyung-Kyun
Journal of the Computational Structural Engineerin.2016; 29(2): 105. CrossRef Failure strain formulation via average stress triaxiality of an EH36 high strength steel
Joonmo Choung, Woongshik Nam, Daeyong Lee, Chang Yong Song
Ocean Engineering.2014; 91: 218. CrossRef Formulation of Failure Strain according to Average Stress Triaxiality of Low Temperature High Strength Steel (EH36)
Joonmo Choung, Woongshik Nam
Journal of Ocean Engineering and Technology.2013; 27(2): 19. CrossRef Finite Element Simulation of Elastic Waves for Detecting Defects and Deteriorations in Underwater Steel Plates
Jinho Woo, Won-Bae Na
Journal of Ocean Engineering and Technology.2013; 27(3): 61. CrossRef On the Fracture of Polar Class Vessel Structures Subjected to Lateral Impact Loads
Dug-Ki Min, Sang-Rai Cho
Journal of the Society of Naval Architects of Kore.2012; 49(4): 281. CrossRef
|