1 |
Aguirre, F., Vargas, S., Valdes, D., & Tornero, J., 2017. State of the art of parameters for mechanical design of an autonomous underwater vehicle. International Journal of Oceans and Oceanography, 11(1), pp.89-103.
|
2 |
ASME Boiler and Pressure Vessel Code, 2007. Section X: Fiber-Reinforced Plastic Pressure Vessel.
|
3 |
Burcher, R. and Rydill, L., 1994. Concepts in Submarine Design. Cambridge University Press: Cambridge, U.K.
|
4 |
Cho, J.R., Chung, W.B., & Kim, J.S., 2009. UVRC, Division of underwater structure and vibration research, 2nd Phase Report, ADDR-413-091956, Daejeon: Agency for Defense Development, Republic of Korea.
|
5 |
Cho, Y.S., 2005, Structural strength calculation method and program manual for pressure hull, NSDC-513-051385, Daejeon: Agency for Defense Development, Republic of Korea.
|
6 |
Cho, Y.S., Oh, D.H., & Paik, J.K., 2019, An empirical formula for predicting the collapse strength of composite cylindrical-shell structures under external pressure loads. Ocean Engineering 172, pp.191-198.
DOI
|
7 |
Cho, Y.S. & Paik, J.K., 2017. Optimal design of submarine pressure hull structures using genetic algorithm. Journal of the Society of Naval Architects of Korea, 54(5), pp.378-386.
DOI
|
8 |
Dey, A., Choudhury, P.L., & Pandey, K.M., 2014. A computational study of buckling analysis of filament wound composite pressure vessel subjected to hydrostatic pressure. Global Journal of Researches In Engineering A: Mechanical and Mechanics Engineering, 14(2), pp.9-14.
|
9 |
Goldberg, D.E., 1989. Genetic algorithms in search, optimization, and machine learning. Addison- wesley Longman Publishing Co., Inc.: Boston, USA.
|
10 |
Hur, S.H., Son, H.J., Kweon, J.H., & Choi, J.H., 2008. Postbuckling of composite cylinders under external hydrostatic pressure. Composite Structures, 86, pp.114-124.
DOI
|
11 |
Jones, R.M., 1999. Mechanics of composite materials. Taylor & Francis, Inc.: Philadelphia, USA.
|
12 |
Jung, H.Y., Cho, J.R., Han, J.Y., Lee, W.H., Bae, W.B. & Cho, Y.S., 2012. A study on buckling of filament-wound cylindrical shells under hydrostatic external pressure using finite element analysis and buckling formula. International Journal of Precision Engineering and Manufacturing, 13(5), pp.731-737.
DOI
|
13 |
Kim, M.H., Cho, J.R., Bae, W.B., Kweon, J.H., Choi, J.H., Cho, S.R., & Cho, Y.S., 2010. Buckling analysis of filament-wound thick composite cylinder under hydrostatic pressure. International Journal of Precision Engineering and Manufacturing, 11(6), pp.909-913.
DOI
|
14 |
Krishnakumar, K., 1989. Micro-genetic algorithms for stationary and non-stationary function optimization. Proceedings of SPIE 1196, Intelligent Control and Adaptive Systems, pp.282-296.
|
15 |
Messager, T., 2001. Buckling of imperfect laminated cylinders under hydrostatic pressure. Composite Structures, 53, pp.301-307.
DOI
|
16 |
Messager, T., Pyrz, M., Gineste, B., & Chauchot, P., 2002. Optimal laminations of thin underwater composite cylindrical vessels. Composite Structures, 58, pp.529-537.
DOI
|
17 |
Moon, C.J., Kim, I.N., Choi, B.H., Kweon, J.H., & Choi, J.H., 2010. Buckling of filament-wound composite cylinders subjected to hydrostatic pressure for underwater vehicle applications. Composite Structures, 92, pp.2241-2251.
DOI
|
18 |
Perry, T.G., Douglas, C.D., & Gorman, J.J., 1992. Analytical design procedures for buckling-dominated graphite/epoxy pressure hulls. SNAME Transactions, 100, pp.93-115.
|
19 |
Mouritz, A.P., Gellert, E., Burchill, P., & Challis, K., 2001. Review of advanced composite structures for naval ships and submarines. Composite Structures, 53, pp.21-41.
DOI
|
20 |
NASA Space Vehicle Design Criteria, 1968. Buckling of thin-walled circular cylinders. NASA SP-8007, pp.19-21, Washington, D.C.: National Aeronautics and Space Administration, USA.
|
21 |
ROK Navy, 2016. Criteria for structural strength of pressure hull. Design and Building Criteria for Submarine, JoHam(Jam)-1-001(0), Daejeon Korea: ROK Navy.
|