Effect of gradient temperature rolling (GTR) and cooling on microstructure and properties of E40-grade heavy plate

Gaosheng, L.; Wei, Y.; Qingwu, C.; He, Z.

doi:10.1016/j.acme.2016.09.004

Artykuł - szczegóły

Tytuł artykułu

Effect of gradient temperature rolling (GTR) and cooling on microstructure and properties of E40-grade heavy plate

Autorzy

Gaosheng L. , Wei Y. , Qingwu C. , He Z.

Wybrane pełne teksty z tego czasopisma

http://www.springer.com/journal/43452

Identyfikatory

DOI

10.1016/j.acme.2016.09.004

Warianty tytułu

Języki publikacji

Abstrakty

Despite numerous investigations on gradient temperature rolling (GTR) and its influence on grain refining, no research exists on appropriate cooling after GTR, which is important in the microstructural control. This work focuses on the effect of final microstructure on heavy-plate properties and microstructural evolution during different rolling and cooling processes. GTR and uniform temperature rolling (UTR) were applied to E40-grade heavy plates. GTR plates were maintained at 1073 K at their surface and 1473 K at their core. After rolling, experimental plates were cooled at a series of rates. Their microstructure and mechanical properties were studied. The plate prepared using GTR and air cooling had the best integrated property because of its uniform and fine ferrite microstructure. The GTR plate strength increased gradually with a corresponding decrease in toughness as the cooling rate increased. The uniform temperature rolling plate cooled in water exhibited the worst mechanical properties.

Słowa kluczowe

gradient temperature rolling cooling grain refinement strength toughness

chłodzenie wytrzymałość siła

Wydawca

Springer
Wrocław University of Science and Technology

Czasopismo

Archives of Civil and Mechanical Engineering

Rocznik

2017

Tom

Vol. 17, no. 1

Strony

121--131

Opis fizyczny

Bibliogr. 27 poz., rys., tab., wykr.

Twórcy

autor

Gaosheng L.

National Engineering Research Center for Advanced Rolling of USTB, Beijing 100083, China

autor

Wei Y.

yuwei9451@163.com

National Engineering Research Center for Advanced Rolling of USTB, Beijing 100083, China

autor

Qingwu C.

National Engineering Research Center for Advanced Rolling of USTB, Beijing 100083, China

autor

He Z.

Industrial and Manufacturing System Engineering, Iowa State University, 50014, USA

Bibliografia

[1] S.K. Ghosh, A. Haldar, P.P. Chattopadhyay, The influence of copper addition on microstructure and mechanical properties of thermomechanically processed microalloyed steels, Journal of Materials Science 44 (2) (2009) 580–590.
[2] A. Lambert-Perlade, A.F. Gourgues, A. Pineau, Austenite to bainite phase transformation in the heat-affected zone of a high strength low alloy steel, Acta Materialia 52 (8) (2004) 2337–2348.
[3] Y.Q. Zhang, H.Q. Zhang, W.M. Liu, et al., Effects of Nb on microstructure and continuous cooling transformation of coarse grain heat-affected zone in 610 MPa class high-strength low-alloy structural steels, Materials Science and Engineering: A 499 (1) (2009) 182–186.
[4] V. Torabinejad, A. Zarei-Hanzaki, S. Moemeni, An analysis to the kinetics of austenite recrystallization in Fe-30Mn-5Al steel, Materials and Manufacturing Processes 28 (1) (2012) 36– 41.
[5] A. Najafi-Zadeh, S. Yue, J.J. Jonas, Influence of hot strip rolling parameters of austenite recrystallization in interstitial free steels, ISIJ International 32 (2) (1992) 213–221.
[6] W. Deng, D. Zhao, X. Qin, et al., Simulation of central crack closing behavior during ultra-heavy plate rolling, Computational Materials Science 47 (2) (2009) 439–447.
[7] Y.C. Jang, Y. Lee, G.B. An, et al., Temperature dependent fracture model and its application to ultra heavy thick steel plate used for shipbuilding, International Journal of Modern Physics B 22 (31n32) (2008) 5483–5488.
[8] Y. Wei, L. Gaosheng, C. Qingwu, Effect of a novel gradient temperature rolling process on deformation, microstructure and mechanical properties of ultra-heavy plate, Journal of Materials Processing Technology 217 (2015) 317–326.
[9] Y. Wei, L. Gaosheng, C. Qingwu, Q345 ultra-heavy plate rolled with temperature gradient, Materials and Manufacturing Processes 30 (1) (2015) 104–110.
[10] G. Krauss, S.W. Thompson, Ferritic microstructures in continuously cooled low-and ultra low-carbon steels, ISIJ International 35 (8) (1995) 937–945.
[11] J. Hu, L.X. Du, J.J. Wang, et al., Effect of welding heat input on microstructures and toughness in simulated CGHAZ of V–N high strength steel, Materials Science and Engineering: A 577 (2013) 161–168.
[12] D. Liu, Q. Li, T. Emi, Microstructure and mechanical properties in hot-rolled extra high-yield-strength steel plates for offshore structure and shipbuilding, Metallurgical and Materials Transactions A 42 (5) (2011) 1349–1361.
[13] A. Abdollah-Zadeh, B. Eghbali, Mechanism of ferrite grain refinement during warm deformation of a low carbon Nb-microalloyed steel, Materials Science and Engineering: A 457 (1) (2007) 219–225.
[14] H. Dong, X. Sun, Deformation induced ferrite transformation in low carbon steels, Current Opinion in Solid State and Materials Science 9 (6) (2005) 269–276.
[15] J. Lewis, J.J. Jonas, B. Mintz, The formation of deformation induced ferrite during mechanical testing, ISIJ International 38 (3) (1998) 300–309.
[16] Z.D. Li, Z.G. Yang, C. Zhang, et al., Influence of austenite deformation on ferrite growth in a Fe–C–Mn alloy, Materials Science and Engineering: A 527 (16) (2010) 4406–4411.
[17] J.W. Fan, X.L. Dai, R.P. Xie, et al., Surface ferrite grain refinement and mechanical properties of low carbon steel plates, International Journal of Iron and Steel Research 13 (4) (2006) 35–39.
[18] G. Di, Z. Liu, X. Liu, et al., On the low-carbon plate steel E40- Z35 for offshore platform, Journal of Northeastern University (Natural Science) 11 (2009) 1582–1585 (in Chinese).
[19] L. Gaosheng, Y. Wei, C. Qingwu, Investigation of the evolution of central defects in ultra-heavy plate rolled using gradient temperature process, Metallurgical and Materials Transactions B 46 (2) (2015) 831–840.
[20] R.H. Edwards, N.F. Kennon, Kinetics of bainite formation from deformed austenite, Journal of the Australian Institute of Metals 19 (1) (1974) 45–50.
[21] M.C. Zhao, Y.Y. Shan, F.R. Xiao, et al., Acicular ferrite formation during hot plate rolling for pipeline steels, Materials Science and Technology 19 (3) (2003) 355–359.
[22] M.C. Zhao, K. Yang, Y.Y. Shan, Comparison on strength and toughness behaviors of microalloyed pipeline steels with acicular ferrite and ultrafine ferrite, Materials Letters 57 (9) (2003) 1496–1500.
[23] B. Xie, Q. Cai, W. Yu, et al., Effect of tempering temperature on resistance to deformation behavior for low carbon bainitic YP960 steels, Materials Science and Engineering: A 618 (2014) 586–595.
[24] A. Kumar, S.B. Singh, K.K. Ray, Influence of bainite/ martensite-content on the tensile properties of low carbon dual-phase steels, Materials Science and Engineering: A 474 (1) (2008) 270–282.
[25] H. Sakamoto, K. Toyama, K. Hirakawa, Fracture toughness of medium-high carbon steel for railroad wheel, Materials Science and Engineering A285 (1) (2000) 288–292.
[26] Q. Sun, X.N. Wang, S.H. Zhang, L.X. Du, H.S. Di, Effect of microstructure on fracture toughness of new type hot-rolled nano-scale precipitation strengthening steel, Acta Metallurgica Sinica 49 (2013) 1501–1507 (in Chinese).
[27] J. Hu, L.X. Du, J.J. Wang, et al., Structure–mechanical property relationship in low carbon microalloyed steel plate processed using controlled rolling and two-stage continuous cooling, Materials Science and Engineering: A 585 (2013) 197–204.

Uwagi

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017)

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-efba46ae-fa04-408d-9f0d-fa447448c30c