A Novel Concept of High Cu, Low Mn, Environmentally-Friendly Weathering Steels

Osvaldo Comineli

doi:10.4028/www.scientific.net/MSF.783-786.698

Paper Titles

Development of Ultra-Fine Grained Dual-Phase Steels: Mechanism of Grain Refinement during Inter-Critical Deformation
p.674

Microstructure Evolution of Martensitic Ti-6Al-4V Alloy during Warm Deformation
p.679

Thermo-Mechanically Controlled Processed Ultrahigh Strength Steels
p.685

Heat Treatment Effects on Distortion, Residual Stress, and Retained Austenite in Carburized 4320 Steel
p.692

A Novel Concept of High Cu, Low Mn, Environmentally-Friendly Weathering Steels
p.698

The Mechanism of Martensite-Austenite Microconstituents Formation during Thermomechanical Controlling Processing in Low Carbon Bainitic Steel
p.704

Fatigue Behavior of High Manganese TWIP Steels and of Low Alloy Q&P Steels for Car-Body Applications
p.713

Cold Rolled Superfine Steel
p.721

Influence of Heat Treatment on Values of a Strain of Interstitial Free Steel
p.726

HomeMaterials Science ForumMaterials Science Forum Vols. 783-786A Novel Concept of High Cu, Low Mn,...

A Novel Concept of High Cu, Low Mn, Environmentally-Friendly Weathering Steels

Abstract:

A novel concept of hot shortness control on copper containing weathering steels is proposed. The weathering effect of copper addition in steels and its improvement in the mechanical and impact properties by age hardening are well known. Again, it is also very well know the problem of cracks on hot processing of those steels, caused by liquid copper segregation, the “hot shortness”. Hot shortness is the main problem of commercial producing of copper containing steels because of the increase of cost production caused by cracks the Ni addition to prevent them. Recent research found that copper segregates surrounding MnS inclusions in the steel, worsening the copper segregation caused by the preferential oxidation of iron on the hot processing of copper containing steels, which is the traditional cause of the “hot shortness”. The same results also show that copper additionally precipitates as CuS in the bulk of the steel. This work points that the “hot shortness” can then be prevented by reducing the Mn in the steel, rather than by the expensive Ni addition. Reducing Mn means reduction of inclusions of MnS sites for copper segregation in the steel. Residual sulphur can therefore be trapped by the copper as finer CuS precipitates, so copper is then dissolved in the bulk of the steel rather than segregated. This paper introduces an alternative solution for the problem of the “hot shortness” by partially or fully replacing the Mn by Cu in those steels. It is then proposed a novel concept of low Mn, or Mn free, Cu containing weathering steels in which Cu replaces Mn in trapping the S. That new steel opens the possibility to a cheaper and easier controls of the “hot shortness” so the copper contamination from scraps become a technological benefit because of its age hardening and weathering effect on steels. The recycling of highly copper contaminated scraps is another important environmental advantage. The conclusion of this work is that the current results introduces a new technology of cheaper copper containing low Mn, or Mn free, high strength, environmentally-friendly weathering steels with high potential market for different welded on shore and offshore specifications.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Materials Science Forum (Volumes 783-786)

Pages:

698-703

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.783-786.698

Citation:

Cite this paper

Online since:

May 2014

Authors:

Osvaldo Comineli*

Keywords:

Copper Steels, CuS, Hot Shortness, Inclusion, Weathering Steels

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] VAYNMAN, S.; FINE, M. E. and BHAT, S. P., High Strength Copper Steel for Rail Tank Cars to Bridges. Copper Applications in Metallurgy of Copper and Copper Alloys, (2006).

Google Scholar

[2] HARLEY, A. J.; ESTBURN, P. and LEECE, N., In: RESIDUALS ADDITIVES AND MATERIALS PROPERTIES. The Royal Society, London, UK , 1980, pp.45-55.

Google Scholar

[3] JARDIM, J. C.; COMINELI, O. and DIPPENAAR, R., Investigations on the Influence of Nickel on the HOT SHORTNESS, of C-Mn-Al, Cu containing steels. In: 45th ROLLING SEMINAR - Associação Brasileira de Metalurgia e Materiais, 2008, Porto de Galinhas, PE, Brazil: ABM, (2008).

Google Scholar

[4] COMINELI, O.; KARJALAINEN, L. P. and DIPPENAAR, R., The Influence of Inclusions on the HOT SHORTNESS, of Cu Containing Steels. In: 62nd ANNUAL CONFERENCE OF ASSOCIAÇÃO BRASILEIRA DE METALURGIA E MATERIAIS, 2007, Vitória, ES, Brazil: ABM, 2007. ref. 11999.

Google Scholar

[5] COMINELI, O.; TULING, A.; MINTZ, B. and KARJALAINEN, L. P., The Influence of a Small Ti Addition on the HOT DUCTILITY of Cu Containing Steels. In: 62nd ANNUAL CONFERENCE OF ASSOCIAÇÃO BRASILEIRA DE METALURGIA E MATERIAIS, 2007, Vitória, ES, Brazil: ABM, 2007. ref. 11998.

Google Scholar

[6] COMINELI, O.; MINTZ, B. and KARJALAINEN, L. P., The influence of cooling rate on the hot ductility of Cu containing steels. In: XXXVII STEELMAKING SEMINAR - ASSOCIAÇÃO BRASILEIRA DE METALURGIA E MATERIAIS, 2006, Porto Alegre, RS, Brazil: ABM, (2006).

Google Scholar

[7] MINTZ, B.; COMINELI, O. and KARJALAINEN, L. P., The Influence of Ni on the Hot Ductility of C-Mn-Al, Cu Containing Steels as a Way of preventing Hot Shortness,. In: 59th ANNUAL CONFERENCE OF ASSOCIAÇÃO BRASILEIRA DE METALURGIA E MATERIAIS, 2004, São Paulo, SP, Brazil: ABM, 2004. ref. 3638.

DOI: 10.3989/revmetalm.2005.v41.iextra.1065

Google Scholar

[8] COMINELI, O; LUO, H.; LIIMATAINEN, H-M and KARJALAINEN, L. P., Influence of Ni Alloying on Hot Ductility of Ti-Nb Microalloyed Steels. In: 59thANNUAL CONFERENCE OF ASSOCIAÇÃO BRASILEIRA DE METALURGIA E MATERIAIS, 2004, São Paulo, SP, Brazil: ABM, 2004. ref. 3639.

DOI: 10.3989/revmetalm.2005.v41.iextra.1065

Google Scholar

[9] COMINELI, O.; LUO, H.; LIIMATAINEN, H-M and KARJALAINEN, L. P., Influence of Cu alloying on hot ductility of C-Mn-Al and Ti-Nb microalloyed steels. Revista de Metalurgia, Vol. Extr. pp.407-411.

DOI: 10.3989/revmetalm.2005.v41.iextra.1065

Google Scholar

[10] COMINELI, O.; ABUSHOSHA, R. and MINTZ, B., Influence of Ti and N on the hot ductility of C-Mn-Nb-Al steels. Materials Science and Technology, v. 15, pp.1058-1068, September 1999, The Institute of Materials, 1 Carlton House Terrace, London.

DOI: 10.1179/026708399101506788

Google Scholar

[11] ABUSHOSHA, R.; COMINELI, O and MINTZ, B., Influence of Ti on hot ductility of C-Mn-Al steels", R. Materials Science and Technology. v. 15, pp.278-286, March 1999, The Institute of Materials, 1 Carlton House Terrace, London.

DOI: 10.1179/026708399101505842

Google Scholar

[12] COMINELI, O., Desenvolvimento de aço patinável com alto Cu, baixo Mn e melhor reciclabilidade de sucata. In: 64th INTERNATIONAL CONFERENCE OF ASSOCIAÇÃO BRASILEIRA DE METALURGIA E MATERIAIS, 2009, Belo Horizonte, MG, Brazil: ABM, 2009. ref. 3639.

Google Scholar

[13] LINO, Y., Steps toward Building an Environmentally Advanced Steel Works. NKK Technical Review, v. 88, pp.28-36, (2003).

Google Scholar