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HomeMaterials Science ForumMaterials Science Forum Vols. 783-786Bendability and Microstructure of Direct Quenched...

Bendability and Microstructure of Direct Quenched Optim^® 960QC

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Abstract:

Use of ultra-high-strength steels (UHSS) in weight critical constructions is an effective way to save energy and minimize carbon footprint in the end use. On the other hand, the demands for reducing manufacturing costs and energy consumption of the steelmaker are increasing. This has led to development of energy efficient direct quenching (DQ) steelmaking process as an alternative to the conventional quenched and tempered or thermomechanical rolling and accelerate cooled processes. Ruukki has employed thermomechanical rolling and direct quenching process (TM + DQ) for a novel type of ultra-high-strength strip and plate steels since 2001. Advantages of the ultra-high-strength level (>900MPa) can be fully utilized only if fabricated properties are on a sufficient level. Bending is one of the most important workshop processes and a good bendability is essential for a structural steel. Hence, the metallurgy and bendability of Ruukki ́s TM + DQ strip steel Optim^® 960QC have been investigated closely. It was found that by optimizing process parameters and chemical composition, a good combination of strength and ductility can be achieved by a modification of martensitic-bainitic microstructure. Despite of smaller total elongation, the bendability of Optim^® 960QC is at least on the same level as on conventionally manufactured 960MPa steels. However, it is important to pay special attention to bending process (tool parameters, springback, bending force, material handling) when bending UHSS. It was also found that the bendability of Optim^® 960QC can be significantly enhanced by local laser heat treatments or roll forming.

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THERMEC 2013

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Periodical:

Materials Science Forum (Volumes 783-786)

Pages:

818-824

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.783-786.818

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Online since:

May 2014

Authors:

Vili Kesti*, A. Kaijalainen, A. Väisänen, A. Järvenpää, A. Määttä, A.M. Arola, K. Mäntyjärvi, R. Ruoppa

Keywords:

Bainite, Bendability, Direct Quenching, Martensite, Ultra-High-Strength Steel

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© 2014 Trans Tech Publications Ltd. All Rights Reserved

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[1] C. Ouichi: Development of steel plates by intensive use of TMCP and direct quenching processes. ISIJ Int. 41 (6) (2001) 542-553.

DOI: 10.2355/isijinternational.41.542

[2] M. Espenhahn, T. Heller, J. Esdohr: US Patent Number 6, 2840, 63. (2001).

[3] Hemmilä, Liimatainen, Liimatainen. Patent Number EP1375694 (A1). (2004).

[4] A.J. Kaijalainen, P.P. Suikkanen, T.J. Limnell, L.P. Karjalainen, J.I. Kömi, D.A. Porter: Effect of austenite grain structure on the strength and toughness of direct-quenched martensite, J. Alloys Compd. (2012).

DOI: 10.1016/j.jallcom.2012.03.030

[5] Information on http: / www. ruukki. com/Products-and-solutions/Steel-products/Hot-rolled-steels/Structural-steels/Optim-QC.

[6] A. Kaijalainen, P. Karjalainen, D. Porter, P. Suikkanen, J. Kömi, V. Kesti, T. Saarinen: Effect of inclusions on the properties of ultra-high-strength low-alloy steel with a martensitic-bainitic microstructure, Proc. 8th Int. Conf. Clean Steel, Budapest, Hungary (2012).

[7] S. K. Paul, S. Mishra: On the formability of sheet steels, Bull. Mater. Sci., Vol 19, No 6, (1996) 963-984.

DOI: 10.1007/bf02744631

[8] T. Gladman: The effects of inclusions on mechanical properties, in F.B. Pickering (Ed): Inclusions. The Institution of Metallurgists (London), Monograph No. 3, 1979, p.157.

[9] R. Ruoppa, J. Sipola, R. Toppila, V. Kesti: Bending properties of some ultra-high-strength steels. Izmir, Turkey, MetNet (2012).

[10] A. Leiviskä, K.P. Mäntyjärvi, J.A. Karjalainen: Bendability of ultra-high-strength steel, Key Engineering Materials Vols. 410-411 (2009) 611-620.

DOI: 10.4028/www.scientific.net/kem.410-411.611

[11] M. Hemmilä, A. Hirvi, J. Kömi, R. Laitinen, M. Lehtinen, P. Mikkonen, D. Porter, J. Savola, S. Tihinen: Technological properties of direct-quenched structural steels with yield strength 900-960MPa as cut lengths and hollow sections. Proc. 2nd International Conference of Super-High Strength Steels. Garda (Verona), Italy (2010).

[12] J.A. Heikkala, A.J. Väisänen: Usability testing of ultra-high-strength steels, Proc. 11th Biennal Conference on Engineering Systems Design and Analysis, Nantes, France, ASME (2012).

[13] A.J. Kaijalainen, P.P. Suikkanen, L.P. Karjalainen, J.I. Kömi, A.J. DeArdo:, Effect of austenite conditioning in the non-recrystallization regime on the microstructures and properties of ultra high strength bainitic/martensitic strip steel, Proc. 2nd Int. Conf. Super-High Strength Steels, Peschiera del Garda, Italy, AIM (2010).

DOI: 10.1016/j.wear.2020.203336

[14] R.K. Ray, J.J. Jonas, M.P. Butron-Guillen, J. Savoie: Transformation textures in steels, ISIJ Int. 34 (1994) 927-942.

DOI: 10.2355/isijinternational.34.927

[15] A. Määttä, A. Järvenpää, M Jaskari, K. Mäntyjärvi, J.A. Karjalainen: Influence of Predetermined Surface Defect to the Bendability of Ultra-High-Strength Steel, Key Engineering Materials Vols. 504-506 (2012) 901-906.

DOI: 10.4028/www.scientific.net/kem.504-506.901

[16] ISO EN 10025-6. Hot rolled products of structural steels. Part 6: Technical delivery conditions for flat products of high yield strength structural steels in the quenched and tempered condition.

DOI: 10.3403/30239489

[17] K. Yamazaki, Y. Mizuyama, M. Oka, Y. Tokunaga: Influence of microstructure on bendability of ultrahigh-strength steel sheet-formability of ultrahigh-strength steel sheet. Journal of the Japan Society for Technology of Plasticity (Japan) 36. 416 (1995).

[18] K. Yamazaki, Y Mizuyama, M. Oka, H. Tsuchiya, H. Yasuda: Recent advances in Ultrahigh-Strength Sheet Steels for Automotive Structural use, Nippon Steel technical report No. 64 (1995) 37-44.

DOI: 10.1016/s0142-1123(97)90062-1

[19] A. Järvenpää, P. Karjalainen, K. Mäntyjärvi: Passive laser assisted bending of ultra-high strength steels, Adv. Mater. Res. 418-420 (2012) 1542-1547.

DOI: 10.4028/www.scientific.net/amr.418-420.1542

[20] A. Järvenpää, K. Mäntyjärvi, M. Merklein, A. Määttä, M. Hietala, J. Karjalainen: Mechanical Properties of Laser Heat Treated 6 mm Thick UHSS-Steel. In: Menary, G. (Ed. ): The 14th International ESAFORM Conference on Material Forming, 1353(2011).

DOI: 10.1063/1.3589699

[21] K. Mäntyjärvi, M. Merklein, J. A. Karjalainen: UHS Steel Formability in Flexible Roll Forming. Key Engineering Materials Vols. 410-411 (2009) 661-668.

DOI: 10.4028/www.scientific.net/kem.410-411.661