{"title":"Elasto-Visco-Plastic-Damage Model for Pre-Strained 304L Stainless Steel Subjected to Low Temperature","authors":"Jeong-Hyeon Kim, Ki-Yeob Kang, Myung-Hyun Kim, Jae-Myung Lee","volume":61,"journal":"International Journal of Mechanical and Mechatronics Engineering","pagesStart":29,"pagesEnd":35,"ISSN":"1307-6892","URL":"https:\/\/publications.waset.org\/pdf\/4974","abstract":"
Primary barrier of membrane type LNG containment system consist of corrugated 304L stainless steel. This 304L stainless steel is austenitic stainless steel which shows different material behaviors owing to phase transformation during the plastic work. Even though corrugated primary barriers are subjected to significant amounts of pre-strain due to press working, quantitative mechanical behavior on the effect of pre-straining at cryogenic temperatures are not available. In this study, pre-strain level and pre-strain temperature dependent tensile tests are carried to investigate mechanical behaviors. Also, constitutive equations with material parameters are suggested for a verification study.<\/p>\r\n","references":"[1] W.S. Lee, C.F. Lin, \"Comparative study of the impact response and\r\nmicrostructure of 304L stainless steel with and without prestrain\", Metall.\r\nMater. Trans. A, vol. 33, pp. 2801-2810, 2002\r\n[2] Y. Iino, \"Effect of small and large amounts of prestrain at 295K on tensile\r\nproperties at 77K of 304 stainless steel\", JSME Int J., Ser. A, vol. 35,\r\npp.303-309, 1992\r\n[3] L.T. Robertson, T.B. Hilditch, P.D. Hodgson, \"The effect of prestrain and\r\nbake hardening on the low cycle fatigue properties of TRIP steel\", Int. J.\r\nFatigue, vol. 30, pp.587-594, 2008\r\n[4] W. S. Park, S. W. Yoo, M. H. Kim, and J. M. Lee, \"Strain-rate effects on\r\nthe mechanical behavior of the AISI 300 series of austenitic stainless steel\r\nunder cryogenic environments\", Mater. Des. Vol. 31, pp. 3630-3640,\r\n2010\r\n[5] K.J. Lee, M.S. Chun, M.H. Kim, J.M. Lee. \"A new constitutive model of\r\naustenitic stainless steel for cryogenic applications\", Comp Mater Sci.,\r\nvol. 46, pp. 1152-1162, 2009\r\n[6] G.B. Olson, M. Cohen. Metall. Mater. Trans. A, vol. 6, pp. 791-795, 1975\r\n[7] Tomita, Y., Iwamoto, T., \"Computational prediction of deformation\r\nbehavior of TRIP steels under cyclic loading\", Int. J. Mech. Sci., vol. 43,\r\npp. 2017-2034, 2001\r\n[8] C. Garion, B. Skocze\u0144, S. Sgobba, \"Constitutive modelling and\r\nidentification of parameters of the plastic strain-induced martensitic\r\ntransformation in 316L stainless steel at cryogenic temperatures\", Int. J.\r\nPlast., vol. 22, pp. 1234-1264, 2006\r\n[9] Y. Tomita, T. Iwamoto, Int. J. Mech. Sci. vol. 37, no. 12, pp. 1295-1305,\r\n1995\r\n[10] W. S. Park, C. S. Lee, M. S. Chun, M, H. Kim, J. M. Lee, \"Comparative\r\nstudy on mechanical behavior of low temperature application materials\r\nfor ships and offshore structures: Part II - Constitutive model\", Mater Sci\r\nEng A., vol. 528, pp. 7560-7569, 2011\r\n[11] Bodner, S. R., Unified Plasticity for Engineering Applications .Kluwer\r\nAcademic\/ Plenum Publishers, 2002\r\n[12] L. Durrenberger, J.R. Klepaczko and A. Rusinek, \"Constitutive modeling\r\nof metals based on the evolution of the strain hardening rate\", J. Eng.\r\nMater. Technol., vol. 129, pp.550-558, 2007\r\n[13] I.K. Senchenkov and G.A.Tabieva, \"Determination of the parameters of\r\nthe Bodner-Partom model for thermoviscoplastic deformation of\r\nmaterials\", Int. Appl. Mech., vol. 32, pp.132-139, 1996\r\n[14] D.R. Hayhurst and F.A. Leckie, \"Constitutive Equation for Creep\r\nDamage\", Acta Metall., vol. 25, pp.1059-1070, 1977\r\n[15] C. Zener and J.H. Hollomon, J. appl. Phys., vol. 15, pp. 22, 1944","publisher":"World Academy of Science, Engineering and Technology","index":"Open Science Index 61, 2012"}