Your search keyword '"Seung Jo Kim"' showing total 2 results

1. Experimental study on dynamic buckling phenomena for supercavitating underwater vehicle

Author

Minho Chung, Hee Jun Lee, Yeon Cheol Kang, Woo-Bin Lim, Jeong Ho Kim, Jin Yeon Cho, Wanil Byun, Seung Jo Kim, and Sung-Han Park

Subjects

Dynamic buckling, Parametric resonance, Dynamic compressive load, Supercavitation, Ocean engineering, TC1501-1800, Naval architecture. Shipbuilding. Marine engineering, VM1-989

Abstract

Dynamic buckling, also known as parametric resonance, is one of the dynamic instability phenomena which may lead to catastrophic failure of structures. It occurs when compressive dynamic loading is applied to the structures. Therefore it is essential to establish a reliable procedure to test and evaluate the dynamic buckling behaviors of structures, especially when the structure is designed to be utilized in compressive dynamic loading environment, such as supercavitating underwater vehicle. In the line of thought, a dynamic buckling test system is designed in this work. Using the test system, dynamic buckling tests including beam, plate, and stiffened plate are carried out, and the dynamic buckling characteristics of considered structures are investigated experimentally as well as theoretically and numerically.

Published

2012

2. Buckling analysis and optimal structural design of supercavitating vehicles using finite element technology

Author

Wanil Byun, Min Ki Kim, Kook Jin Park, Seung Jo Kim, Minho Chung, Jin Yeon Cho, and Sung-Han Park

Subjects

Supercavitating vehicle, FEM, Static/dynamic buckling analysis, PSO (Particle Swarm Optimization) algorithm, Ocean engineering, TC1501-1800, Naval architecture. Shipbuilding. Marine engineering, VM1-989

Abstract

The supercavitating vehicle is an underwater vehicle that is surrounded almost completely by a supercavity to reduce hydrodynamic drag substantially. Since the cruise speed of the vehicle is much higher than that of conventional submarines, the drag force is huge and a buckling may occur. The buckling phenomenon is analyzed in this study through static and dynamic approaches. Critical buckling load and pressure as well as buckling mode shapes are calculated using static buckling analysis and a stability map is obtained from dynamic buckling analysis. When the finite element method (FEM) is used for the buckling analysis, the solver requires a linear static solver and an eigenvalue solver. In this study, these two solvers are integrated and a consolidated buckling analysis module is constructed. Furthermore, Particle Swarm Optimization (PSO) algorithm is combined in the buckling analysis module to perform a design optimization computation of a simplified supercavitating vehicle. The simplified configuration includes cylindrical shell structure with three stiffeners. The target for the design optimization process is to minimize total weight while maintaining the given structure buckling-free.

Published

2011