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유탄성을 고려한 선체 구조물의 파랑 중 피로 및 극한 하중의 수치해석

김정현 2016년

논문상세정보
인용/피인용
' 유탄성을 고려한 선체 구조물의 파랑 중 피로 및 극한 하중의 수치해석' 의 주제별 논문영향력
논문영향력 선정 방법
논문영향력 요약
주제
  • 극한하중
  • 선체 유탄성
  • 스프링잉
  • 슬래밍
  • 프러시저
  • 피로하중
  • 휘핑
동일주제 총논문수 논문피인용 총횟수 주제별 논문영향력의 평균
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' 유탄성을 고려한 선체 구조물의 파랑 중 피로 및 극한 하중의 수치해석' 의 참고문헌

  • “현대의 대형상선에 대한 Springing 해석”
    강병철 석사학위논문, 서울대 학교 [2011]
  • 박사
    “수심 변화와 고주파 하중을 고려한 부유식 해양플랫폼의 비선형 운동 해석”
    김태영 박사학위논문, 서울대학교 [2015]
  • 박사
    “선박의 파랑 중 Weak-Scatterer 기반 비선형 운동해석 및 전선 유탄성 해석”
    김경환 박사학위논문, 서울대학교 [2011]
  • von K rm n, Th., 1929, “The impact on seaplane floats during landing”, NACA Technical Note No. 321, Washington, DC, USA.
  • Zhao, R., Faltinsen, O., 1993, “Water entry of two-dimensional bodies”, J.FluidMech. 246, 593–612.
  • Wu, M.K., Moan, T., 2005, “Efficient calculation of wave-induced ship responses considering structural dynamic effects”, Appl.OceanRes. 27, 81–96.
  • Wu, M.K., Hermundstad, O.A., 2002, “Time-domain simulation of waveinduced nonlinear motions and loads and its applications in ship design”, Mar.Struct.15, 461–597.
  • Wirsching, P.H. and Light, C.L., 1980, “Fatigue under wide band random stresses.” J. Struct. Division ASCE, 106(7), 1593-1607.
  • Winterstein, S.R., Ude, T.C., Cornell, C.A., Bjerager, P., Haver, S., 1993, “Environmental parameters for extreme response: Inverse FORM with omission factors”, In: Schu ller, G.I., Shinozuka, M., Yao, J.T.P.(Eds.), Structural Safety and Reliability, A.A.Balkema, Rotterdam, 77–84.
  • Wagner, H., 1932, “ ber Stoss- und Gleitvorg nge an der Oberfl che von Fl ssigkeiten Z”, Angew. Math. Mech. 12, 193-215.
  • Vidic-Perunovic, J., 2005, “Springing response due to bidirectional wave excitation”, PhD.thesis, Technical University of Denmark, Denmark.
  • Tuitman, J.T., 2010, “Hydro-elastic response of ship structures to slamming induced whipping”, PhD.thesis, Delft University of Technology, Delft, The Netherlands.
  • Troesch, A.W., 1997, “Study of the Use of Nonlinear Time Domain Simulation in a Design Loads Generator (DLG)”, Tech. rept. Final Report to the American Bureau of Shipping.
  • Storhaug, G., Vidic-Perunovic, J., Rudinger, F., 2003, “Springing/whipping response of a large ocean going vessel – a comparison between numerical simulations and full scale measurements”, In: Proceedings of hydroelasticity in marine technology. Oxford.
  • Storhaug, G., Moan, T., 2006, “Springing/whipping response of a large ocean going vessel - Investigated by an experimental method”, In: Proceedings of hydroelasticity in marine technology, Wuxi.
  • Storhaug, G., Kahl, A., 2015, “Full scale measurements of torsional vibrations on Post-Panamax container ships”, In: Proceedings of hydroelasticity in marine technology, Split.
  • Storhaug, G., Derbanne, Q., Choi, B.K., Moan, T., Hermundstad, O.A., 2011, “Effect of whipping on fatigue and extreme loading of a 13000 TEU container vessel in bow quartering seas based on model tests”, In: Proceedings of the 30th International Conference on Ocean, Offshore and Arctic Engineering, OMAE2011-49370, Rotterdam, the Netherlands.
  • Storhaug, G., Choi, B.K., Moan, T., Hermundstad, O.A., 2010, “Consequence of whipping and springing on fatigue for an 8600TEU container vessel in different trades based on model tests”, In: Proceeding of the International Symposium on Practical Design of Ships and Other Floating Structures, PRADS2010.
  • Storhaug, G., 2007, “Experimental Investigation of Wave Induced Vibrations Increasing Fatigue Damage in Ships”, PhD.thesis, Norwegian University of Science and Technology, Tronheim, Norway.
  • Senjanović , I., Tomaš ević , S., Rudan, S., Senjanović , T., 2009, “Role of transverse bulkheads in hull stiffness of large containerships”, Eng.Struct.30(9), 2492–2509.
  • Remy, F., Molin, B., Ledoux, A., 2006, “Experimental and numerical study of the wave response of a flexible barge”, In: Proceedings of hydroelasticity in marine technology, Wuxi.
  • Ogilvie, T.F., Tuck, E.O.,1969, “A Rational Strip Theory for Ship Motions, Part1”, Technical Report013, Department of Naval Architecture and MarineEngineering, The University of Michigan.
  • Ochi, M. K., 1964, “Prediction of occurrence and severity of ship slamming at sea”, In: Proc. 5th Symp. on Naval Hydrodynamics, Bergen, Norway.
  • Oberhagemann, J., Kromer, M., Cabos, C., El Moctar, O., 2012, “A fluidstructure coupling method based on field methods and a structural mode decomposition”, In: Proceedings of hydroelasticity in marine technology, Tokyo.
  • Nakos, D.E., 1990, “Ship Wave Patterns and Motions by a Three Dimensional Rankine Panel Method”, PhD.thesis, Massachusetts Institute of Technology, USA.
  • Moe, E., Holtsmark, G., Storhaug, G., 2005, “Full scale measurements of the wave induced hull girder vibrations of an ore carrier trading in the North Atlantic”, In: Transactions of Royal Institution of Naval Architects, conference on design and operation of bulk carriers, London, UK.
  • Miyake, R., Matsumoto, T., Zhu. T., 2009, “Experimental studies on the hydroelastic response using a flexible mega-containership model”, In: Proceedings of the hydroelasticity in marine technology, Southampton.
  • Mei, X., Liu, Y., Yue, D.K.P., 1999, “On the water impact of general two172 dimensional sections”, Applied Ocean Research 21, 1–15.
  • Mar n, A., Kapsenberg, G., 2014, “Design of a ship model for hydro-elastic experiments in waves”, Int. J. Nav. Archit. Ocean Eng. 6, 1130-1147.
  • Malenica, S., Tuitman, J.T., 2008, “3DFEM–3D BEM model for springing and whipping analysis of ships”, In: Proceedings of the International Conference on Design and Operation of Containerships, London.
  • Malenica, S., Molin, B., Senjanociv, I., 2003, “Hydroelastic response of a barge to impulsive and non-impulsive wave loads”, In: Proceedings of hydroelasticity in marine technology, Oxford.
  • Kring, D.C., 1994, “Time Domain Ship Motions by a Three-dimensional Rankine Panel Method”, PhD.thesis, Massachusetts Institute of Technology, USA.
  • Korea Research Institute of Ships and Ocean Engineering/Korea Institute of Ocean Science and Technology (KRISO/KIOST), 2014, “Wave Induced Loads on Ships Joint Industry Project-III Report.” Report No BSPIS7230-10572-6, Korea.
  • Koning, J., Kapsenberg, G., 2012, “Full scale containership cross section loads – first results”, In: Proceedings of hydroelasticity in marine technology, Tokyo.
  • Kim, Y., Kim, K.H., Kim, Y., 2009c, “Springing analysis of seagoing vessel using fully coupled BEM–FEM in the time domain”, OceanEng.36, 785–796.
  • Kim, Y., Kim, K.H., Kim, Y., 2009b, “Analysis of hydroelasticity of floating ship-like structures in time domain using a fully coupled hybrid BEM–FEM”, J.ShipRes. 53(1), 31–47.
  • Kim, Y., Kim, K.H., Kim, Y., 2009a. “Time domain springing analysis on a floating barge under oblique wave”, J.Mar.Sci.Technol.14, 451–468.
  • Kim, Y., Kim, K.H., Kim, J.H., Kim, T., Seo, M.G., Kim, Y., 2011, “Timedomain analysis of nonlinear motion responses and structural loads on ships and offshore structures: development of WISH programs”, Int.J.Nav.Archit. OceanEng. 3, 37–52.
  • Kim, Y., Kim, J.H., Kim, Y., Lee, D.Y., Jung, B.H., 2015c, “Development of Computational Methods and Application Procedure for Ship Structural Hydroelasticity and Fatigue Assessment in Ocean Waves”, In: Proceedings of the World Maritime Technology Convention 2015, Rhode Island, USA.
  • Kim, Y., 2009, “Time-Domain Analysis on Hull-Girder Hydroelasticity by Fully Coupled BEM-FEM Approach”, PhD.thesis, Seoul National University, Korea.
  • Kim, K.H., Kim, Y., 2008, “On technical issues in the analysis of nonlinear shipmotion and structural loads in waves by a time-domain Rankine panelmethod”, In: Proceedings of the 23rd International Workshop on Water Waves & Floating Bodies, Jeju, Korea.
  • Kim, K.H., Kim, B.W., Hong, S.Y., 2015b, “Experimental Study on Correlation between Slamming Impact and Whipping Vibration for an Ultra-large Containership”, In: Proceedings of hydroelasticity in marine technology, Split.
  • Kim, K.H., Bang, J.S., Kim, J.H., Kim, Y., Kim, S.J., Kim, Y., 2013, “Fully coupled BEM–FEM analysis for ship hydroelasticity in waves”, Mar.Struct.33, 71–99.
  • Kim, J.H., Kim, Y., Yuck, R.H., Lee, D.Y., 2015a, “Comparison of Slamming and Whipping Loads by Fully Coupled Hydroelastic Analysis and Experimental Measurement”, Journal of Fluids and Structures, 52, 145-165.
  • Kim, J.H., Kim, Y., 2015, “Parametric Study of Numerical Prediction of Slamming and Whipping and an Experimental Validation for a 10,000-TEU Containership”, Journal of Advanced Research in Ocean Engineering, 1(2), 115- 133.
  • Kim, J.H., Kim, Y., 2014, “Numerical Analysis on Springing and Whipping using Fully-Coupled FSI Models”, Ocean Engineering, 91, 28-50.
  • Kim, J.H., Kang, B.C., Kim, Y., Kim, Y., 2012, “Ship springing analysis for a very large containership,” International Journal of Offshore and Polar Engineering, 22(3), 217-224.
  • Ki, H.G., Park, S.G., Jang, I.H., 2015, “Full scale measurement of 14k TEU containership”, In: Proceedings of hydroelasticity in marine technology, Split.
  • Khabakhpasheva, T.I., Kim, Y., Korobkin, A.A., 2014, “Generalized Wagner model of water impact by numerical conformal mapping”, Appl.OceanRes.44, 29–38.
  • Kawai, T., 1973, “The application of finite element methods to ship structures”,
  • Jensen, J.J., Dogliani, M., 1996, “Wave-induced ship hull vibrations in stochastic seaways”, Mar.Struct. 9, 353–387.
  • Jensen, J. J., 2008, “Extreme Value Predictions and Critical Wave Episodes for Marine Structures by FORM”, Ships and Offshore Structures, 3(4), 325-333.
  • Iron, B.M., Tuck, R.C., 1969, “A version of the Aitken accelerator for computer interaction”, Int.J.Numer.MethodsEng.1, 275–277.
  • Iijima, L., Hermundstad, O.A., Zhu, S., Moan, T., 2009, “Symmetric and antisymmetric vibrations of a hydroelastically scaled model", In: Proceedings of the hydroelasticity in marine technology, Southampton.
  • Iijima, K., Yao, T., Moan, T., 2008, “Structural response of a ship in severe seas considering global hydroelastic vibrations”, Mar.Struct. 21, 420–445.
  • Hong, S.Y., Kim, B.W., Nam., B.W., 2012, “Experimental Study on Springing and Whipping of a Large Container Ship”, In: Proceedings of International Journal of Offshore and Polar Engineering, 22(2), 97-107.
  • Hirdaris, S.E., Bai, W., Dessi, D., Ergin, A., Gu, X., Hermundstad, O.A., Huijsmans, R., Iijima, K., Nielsen, Parunov, U.D., Fonseca, J. N., Papanikolaou, A., Argyriadis, K., Incecik, A., 2014, “Loads for use in the design of ships and offshore structures”, Ocean Engineering, 78(1), 131-174.
  • Guedes Soares, C., 1993, “Long term distribution of non-linear wave induced vertical bending moments”, Mar.Struct. 6(5–6), 475–483.
  • Gjelsvik, A., 1981, “The Theory of Thin Walled Bars”, John Wiley & Sons, NewYork.
  • Gaspar, B., Teixeira, A.P, Guedes Soares, C., 2015, “Effect of the nonlinear vertical wave-induced bending moments on the ship hull girder reliability”, Online available, Ocean Engineering.
  • Fukuda, J., 1967, “Theoretical determination of design wave bending moments”, in Japanese, Shipbuild. Mar.Eng. 2(3), 13–22.
  • Fujitani, Y., 1991, “Thin-Walled Beam Structural Analysis”, in Japanese, Baihukan Book Company, Tokyo.
  • Drummen, I., 2008, “Experimental and numerical investigation of nonlinear wave induced load effects in containerships considering hydroelasticity”, Ph.D. thesis, Department of Marine Technology, Norwegian University of Science and Technology, Trondheim, Norway.
  • Dirlik, T., 1985, “Application of computers in fatigue analysis”, PhD Thesis, University of Warwick, UK.
  • Dietz, J.S., 2004, “Application of Conditional Waves as Wave Episodes for Extreme Loads on Marine Structures”, PhD. Thesis, Technical University of Denmark, Lyngby.
  • DNV-GL, 2015b, “Fatigue assessment of ship structures.” Class Guideline, DNV-GL-CG-0129, DNV-GL.
  • DNV-GL, 2015a, “Fatigue and ultimate strength assessment of container ships including whipping and springing”, Class Guideline, DNV-GL-CG-0153, DNV-GL.
  • Comput. Struct. 3(5), 1175–1194.
  • Choi J.H., Jung B.H., Hwang J.H., 2013, “Evaluation of Springing-induced Fatigue Damage for Ultra-large Container Carrier”. In: Proceedings of 23rd ISOPE Conference, Anchorage, AK, USA.
  • Bishop, R.E.D., Price, W.G., 1979, “Hydroelasticity of Ships”, Cambridge University Press, London. 168
  • Bigot F., Sireta, F.X., Baudin, E., Derbanne, Q., Tiphine, E., Malenica, S., 2015, “A novel solution to compute time series in nonlinear hydro-structure simulations”, In: Proceedings of the 34th International Conference on Ocean, Offshore and Arctic Engineering, OMAE2015-42014, St. John’s, NL, Canada.
  • Benasciutti, D. and Tovo, R., 2004, “Rainflow cycle distribution and fatigue damage in Gaussian random loadings.” Report, University of Ferrara, Italy.
  • Belgova, M., 1962, “Determination of overall bending moments caused by elastic vibrations of ships”, Trans. of the Leningrad Institute of Water Transport.
  • Baarholm, G.S., Moan, T., 2000, “Estimation of nonlinear long-term extremes of hull girder loads in ships”, Mar.Struct. 13(6), 495–516.
  • BV, 2015, “Whipping and Springing Assessment”, Rule Note, NR 583 DT R01 E, BV.
  • Andersen, I. M. V. and Jensen, J. J., 2014, “Measurements in a Container Ship of Wave-Induced Hull Girder Stresses in Excess of Design Values”, Marine Structures, 37:54–85.
  • ABS, 2014b, “Whipping Assessment for Container Carriers”, Guidance Note, ABS.
  • ABS, 2014a, “Springing Assessment for Container Carriers”, Guidance Note, ABS.