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Materials Science and Technology Volume 38, 2022 - Issue 4
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Research Article

Effect of cold deformation in quench and tempered medium-carbon steel bars microstructure

Virginia H. Arandaa IMA, Facultad de Ingeniería, Universidad Nacional de San Juan, San Juan, ArgentinaCorrespondence[email protected] [email protected]
ORCID Iconhttps://orcid.org/0000-0001-8939-5560
ORCID Icon,
Fernando D. Carazoa IMA, Facultad de Ingeniería, Universidad Nacional de San Juan, San Juan, Argentina;b CONICET, Buenos Aires, ArgentinaORCID Iconhttps://orcid.org/0000-0002-2580-5337
ORCID Icon,
Laura N. Garcíab CONICET, Buenos Aires, Argentina;c ICATE, San Juan, ArgentinaORCID Iconhttps://orcid.org/0000-0002-6860-0665
ORCID Icon,
Diego J. Celentanod CIEN-UC, Santiago, Chile;e Departamento de Ingeniería Mecánica y Metalúrgica, Pontificia Universidad Católica de Chile, Santiago, ChileORCID Iconhttps://orcid.org/0000-0002-7600-0619
ORCID Icon &
Alfredo J. Tolleyb CONICET, Buenos Aires, Argentina;f Centro Atómico Bariloche, Comisión Nacional de Energía Atómica, S.C. de Bariloche, ArgentinaORCID Iconhttps://orcid.org/0000-0002-0844-0137
ORCID Icon
Pages 230-236 | Received 20 Oct 2021, Accepted 27 Jan 2022, Published online: 18 Feb 2022

References

  • Weng Y. Ultra-fine grained steels. 4th ed. Berlin: Springer-Verlag; 2009. p. 10–18.
  • Takaki S, Kawasaki K, Kimura Y. Mechanical properties of ultrafine grained steels. J Mater Process Tech. 2001;117:359–363.
  • Halfa H. Recents trends in producing ultrafine grained steels. J Miner Mater Char Eng. 2014;2:428–469.
  • Arjomandi S, Jafarian H, Park N. A substantial improvement of tensile properties through microstructure engineering in a high Ni-0.2C TRIP steel under severe plastic deformation. Mater Char. 2019;155:109826.
  • Son Y, Lee Y, Park K, et al. Ultrafine grained ferrite-martensite dual phase steels fabricated via equal channel angular pressing: micro-structure and tensile properties. Acta Mater. 2005;53:3125–3134.
  • Okitsu Y, Taketa N, Tsuji N. A new route to fabricate ultrafine-grained structures in carbon steels without severe plastic deformation. Scripta Mater. 2009;60(2):76–79.
  • Zhao L, Park N, Tian Y, et al. Novel thermomechanical processing methods for achieving ultragrain refinement of low-carbon steel without heavy plastic deformation. Mater Res Lett. 2017;5(1):61–68.
  • Sun C, Fu P, Liu H, et al. The effect of lath martensite microstructures on the strength of medium-carbon low-alloy steel. Crystals. 2020;10(3):232–242.
  • Tsuji N, Ueji R, Minamino Y, et al. A new and simple process to obtain nano-structured bulk low-carbon steel with superior mechanical property. Scripta Mater. 2002;46(4):305–310.
  • Ueji R, Tsuji N, Minamino Y, et al. Ultragrain refinement of plain low carbon steels by cold rolling and anneling of martensite. Acta Mater. 2002;50(16):4177–4189.
  • Morito S, Ohba T, Das A, et al. Effect of solution carbon and retained austenite films on the development of deformation structures of low-carbon lath martensite. ISIJ Int. 2013;53(12):2226–2232.
  • Tokizane M, Matsumura N, Tsuzaki K, et al. Recrystallization and formation of austenite in deformed lath martensitic structure of low carbon steels. Metall Trans A. 1982;13:1379–1388.
  • Swarr T, Krauss G. The effect of structure on the deformation of as-quenched and tempered martensite in a Fe-0.2 pct C alloy. Metall Trans A. 1976;7:41–48.
  • Huang X, Morito S, Hansen N, et al. Ultrafine structure and high strength in cold-rolled martensite. Metall Trans A. 2012;43:3517–3531.
  • Morito S, Ohba T, Maki T. Comparison of deformation structure of lath martensite in low and ultra-low carbon steels. Mater Sci Forum. 2007;558:933–938.
  • Lan F, Liu W, Liu X. Ultrafine ferrite grains produced by tempering cold-rolled martensite in low carbon and microalloyed steels. ISIJ Int. 2007;47(11):1652–1657.
  • Lv Z, Qian L, Liu S, et al. Preparation and mechanical behavior of ultra-high strength low-carbon steel. Mater. 2020;13(2):459.
  • Ueji R, Tsuji N, Minamino Y, et al. Effect of rolling reduction on ultrafine grained structure and mechanical properties of low carbon steel thermomechanically processed from martensite starting structure. Sci Tech Adv Mater. 2004;5:153–162.
  • Ghassemali E, Kermanpur A, Najafizadeh A. Microstructural evolution in a low carbon steel during cold rolling and subsequent annealing. J Nanosci Nanotech. 2010;10(9):6177–6181.
  • Maki T, Tsuzake K, Tamura I. The morphology of microstructure composed of lath martensites in steels. Trans ISIJ. 1980;20(4):207–214.
  • Morito S, Huang X, Furuhara T, et al. The morphology and crystallography of lath martensite in alloy steels. Acta Mater. 2006;54(19):5323–5331.
  • Hosseini S, Najafizadeh A, Kermanpur A. Producing the nano/ultrafine grained low carbon steel by martensite process using plane strain compression. J Mater Process Technol. 2011;211(2):230–236.
  • Nakashima K, Fujimura Y, Tsuchiyama T, et al. Work hardening behavior of low carbon martensitic steel. Key Eng Mater. 2007;345–346:189–192.
  • Hayakawa M, Matsuoka S, Furuya Y. Atomic force microscopy of local plastic deformation for tempered martensite. J Jpn I Met Mater. 2003;67(7):354–361.
  • Hayakawa M, Matsuoka S, Furuya Y. Nanoscopic measurement of local plastic deformation for a tempered martensitic steel by atomic force microscopy. Mater Lett. 2003;57(20):3037–3042.
  • Tokizane M, Ameyama K, Takao K. Ultra-fine austenite grain steel produced by thermomechanical processing. Scr Metall. 1988;22(5):697–701.
  • ASTM 322-13. Standard specification for steel bars, alloy, standard grades. 2018.
  • ASTM E415-15. Standard test method for analysis of carbon and low-alloy steel by spark atomic emission spectrometry. 2015.
  • ASTM E384-17. Standard test method for microindentation hardness of materials.
  • Krauss G. Tempering of lath martensite in low and medium carbon steels: assessment and challenges. Steel Res Int. 2017;87:1700038.
  • Hansen N, Jensen D. Development of microstructure in FCC metals during cold work. Phil Trans R Soc A. 1999;357:1447–1469.
  • Lu K, Hansen N. Structural refinement and deformation mechanisms in nanostructured metals. Scripta Mater. 2009;60(12):1033–1038.
  • Bhadeshia H, Edmonds D. Tempered martensite embrittlement: role of retained austenite and cementite. Metal Sci. 1979;13(6):325–334.
  • Flutz B, Howe J. Transmission electron microscopy and diffractometry of materials. 4th ed. Berlin: Springer-Verlag; 2013. p. 46.
  • Tsuji N, Gholizadeh R, Ueji R, et al. Formation mechanism of ultrafine grained microstructures: various possibilities for fabricating bulk nanostructured metals and alloys. Mater Trans. 2019;60(8):1518–1532.

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