International Journal of Naval Architecture and Ocean Engineering

  • 제1권2호
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  • Pages.95-100
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  • 2009
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  • 2092-6782(pISSN)
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  • 2092-6790(eISSN)
대한조선학회 (The Society of Naval Architects of Korea)
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Thermal distortion analysis method for TMCP steel structures using shell element

  • Ha, Yun-sok (Samsung Heavy Industries Co., LTD, 530 Janpyeong-Dong, Geoje, 656-710, South Korea) ;
  • Rajesh, S.R. (Samsung Heavy Industries Co., LTD, 530 Janpyeong-Dong, Geoje, 656-710, South Korea)
  • 발행 : 2009.12.30
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초록

As ships become larger, thicker and higher tensile steel plate are used in shipyard. Though special chemical compositions are required for high-tensile steels, recently they are made by the TMCP (Thermo-Mechanical control process) methodology. The increased Yield / Tensile strength of TMCP steels compared to the normalized steel of same composition are induced by suppressing the formation of Ferrite and Pearlite in favor of strong and tough Bainite while being transformed from Austenite. But this Bainite phase could be vanished by another additional thermal cycle like welding and heating. As thermal deformations are deeply related by yield stress of material, the study for prediction of plate deformation by heating should niflect the principle of TMCP steels. The present study is related to the development of an algorithm which could calculate inherent strain. In this algorithm, not only the mechanical principles of thermal deformations, but also the initial portion of Bainite is considered when calculating inherent strain. Distortion analysis results by these values showed good agreements with experimental results for normalized steels and TMCP steels during welding and heating. This algorithm has also been used to create an inherent strain database of steels in Class rule.

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참고문헌

  1. Jung, G.H. Huang, T.D. Dong, P. Dull, R.M. Conrardy, C.C. and Porter, N.C., 2007. Numerical prediction of buckling in ship panel structure. Journal of Ship Production, 23 (3), pp.171-179
  2. Ha, Y.S. Jang, C.D. Kim, J.T. and Mun, H.S., 2007. Analysis of post-weld deformation at the heat-affected zone using external forces based on the inherent strain. International Journal of Precision Engineering and Manufacturing, 8(4), pp. 56-62
  3. Ha, Y.S. and Jang, C.D., 2006. An improved inherent strain analysis for plate bending by line heating considering phase transformation of steel. International Journal of Offshore and Polar Engineering, 17(2), pp. 139-144
  4. Ha, Y.S., 2007. Development of welding distortion analysis method using residual strain as boundary condition. Samsung Journal of Innovative Technology, 3(1), pp. 173-180
  5. Shin, S.B. Kim, H.G. Kim, K.G. and Yoon, J.G., 2007. A study on the factors affecting the workability of TMCP steel for curved hull plate. In: International Welding and Joining Conference-Korea. Seoul, Korea, 10-12 May 2007
  6. SYSWORLD® 2006. Release notes, ESI Group, 39
  7. SNAK, 2006. Literature survey for the further use of TMCP steel in shipbuilding industries, pp. 3-4
  8. Jang, C.D. Ko, D.E. and Seo, S.I., 1997. A study on the prediction of deformation of plates due to line heating using a simplified thermal elasto-plastic analysis. Journal of Ship Production, 13(1), pp. 22-27.
  9. Atkins, M., 1980. Atlas of continuous cooling transformation diagrams for engineering steels. American Society for Metals, British Steel Corp. (Metals Park, Ohio, Sheffield, Eng), pp. 228-229
  10. Avrami, M., 1939. Kinetics of phase change. I General theory. Journal of Chemical Physics, 7(12), 1103-1112 https://doi.org/10.1063/1.1750380
  11. Marder, A.R. and Krauss, G., 1967. The morphology of martensite in iron-carbon alloys. Trans. ASM, 60, pp. 651-660
  12. Masubuchi, K., 1980. Analysis of welded structures. Oxford, UK: Pergamon Press, pp. 378-380
  13. Gladman,T., 1963. Metallurgical developments in Carbon steels. Special report 81, The Iron and Steel Institute, London, pp. 68-70
  14. ASTM, 1963, Estimating the average grain size of metals. American Society for Testing and Materials Designation, pp. 112-163