Microstructure Evolution in AISI 430 Ferritic Stainless Steel Welds Treated with Aluminum and Titanium Powder Mixture

  • M.O.H. Amuda Materials Development and Processing Research Group, Department of Metallurgical and Materials Engineering, University of Lagos
  • F.T. Lawal Materials Development and Processing Research Group, Department of Metallurgical and Materials Engineering, University of Lagos
  • S. Mridha Department of Mechanical and Aerospace Engineering, University of Strathclyde, G11XJ, Glasgow UK
Keywords: Delta ferrite, ductility, ferritic stainless steel welds, grain refinement, microstructure evolution

Abstract

t
Ferritic stainless steel particularly the AISI 430 standard grade is a candidate material for radiation shielding in
nuclear reactors for power generation at competitive cost than the workhorse AIS1 316L austenitic grade. But its
widespread application as the next generation energy material in nuclear reactor is limited by the loss in
mechanical properties arising from grain coarsening and other phase transformations in the heat affected zone of
the material post-fusion welding. Thus, in this work, attempt was made to resolve the challenge of grain coarsening
in fusion welded AISI 430 ferritic stainless steel for improved mechanical properties. Specifically, the ductility and
tensile strength of AISI 430 ferritic stainless steel welds treated with mixture of aluminum and titanium powder
was investigated in relation to the microstructural evolution in the weld. The columnar structure in the as-welded
condition transited to equiaxed grain with lower percentage of delta ferrite in the powder-mixture treated welds.
In this condition, the ductility and the tensile strength of the treated weld marginally improved by 5 percent. The
present work in relation to existing work in this space established that powder mixture of aluminum and titanium
is capable of producing defect free structural welds in ferritic stainless steel though with marginal improvement in
mechanical properties.

References

Amuda, M. O. H. (2011). Microstructural features and properties of TIG melted AISI 430 ferritic stainless steel
welds. Doctoral Thesis, International Islamic University Malaysia, Kuala Lumpur, Malaysia.
Amuda, M. O. H. and Mridha, S. (2010). Grain refinement in ferritic stainless steel welds: The journey so far.
Advanced Materials Research, 83-86: 1165-1172.
Amuda, M.O.H., Akinlabi, E. T. and Mridha, S. (2017). Influences of energy input and metal powder addition on
carbide precipitation in AISI 430 ferritic stainless steel welds. Materials Today Proceedings, 4(2): 234-243.
Amuda, M.O.H., Akinlabi, E.T. and Mridha, S. (2016). Ferritic stainless steels: Metallurgy, Application and
Weldability. In: Reference Module in Materials Science and Materials Engineering. Elsevier: New York,
USA.
Amuda, M.O.H., Lawal, F.T., Onitiri, M.A., Akinlabi, E.T. and Mridha, S. (2018). Microstructure and Mechanical
Properties of Metal Powder Treated AISI-430 FSS Welds. International Journal of Manufacturing,
Materials, and Mechanical Engineering (IJMMME), 8(4): 63-83.
Anbazhagan, V. and Nagalakshmi, R. (2002). Metallurgical studies in ferritic stainless steel. Welding Research
Institute Journal, 23(3):25–37.
Baldev, R., Kamachi Mudali, U., Vijayalakshmi, M., Mathew, M.D., Bhaduri, A.K., Chellapandi, P., Venugopal, S.,
Sundar, C.S., Rao, B.P.C. and Venkatraman, B. (2013). Development of Stainless Steels in Nuclear Industry:
With Emphasis on Sodium Cooled Fast Spectrum Reactors History, Technology and Foresight. Advanced
Materials Research, 794: 3-25.
Büyükyıldız, M., Kurudirek, M., Ekici, M., İçelli, O. and Karabul, Y. (2017). Determination of radiation shielding
parameters of 304L stainless steel specimens from welding area for photons of various gamma ray sources.
Progress in Nuclear Energy, 100: 245-254.
Cavazos, J.L. (2006). Characterization of precipitates formed in ferritic stainless steel stabilized with Zr and Ti
additions. Material Characterization, 56: 96-101.
Cortie, M., Du Toit, M. (2016). Stainless steels, Ferritic. In: Reference Module in Materials Science and Materials
Engineering. Elsevier: New York, USA.
Delgado, A.J., Ambriz, R.R., Cuenca-Alvarez, R., Alatorre, N. and López, F.F. (2016). Heat input effect on the
microstructural transformation and mechanical properties in GTAW welds of a 409L ferritic stainless steel.
Revista de Metalurgia, 52 (2):68-77
Jozwik, P. and Bojar, Z. (2007). Analysis of grain size effect on tensile properties of Ni3Al-based intermetallic strips.
Archives of Metallurgy and Materials, 2(2): 321-327.
Kamerud, K.L., Hobbie, K.A. and Anderson, K.A. (2013). Stainless steel leaches nickel and chromium into foods
during cooking. Journal of Agricultural and Food Chemistry, 61(39): 9495-9501.
Klas, W. (2012). Weldability of steel. In: Welding Process Handbook. Woodhead Publishing Series in Welding and
Other Joining Technologies. 2nd edition. 191-206.
Kou, S. (2003). Welding metallurgy. 2nd edn. John-Wiley & Sons, New Jersey.
Lancaster, J. F. (1993). Metallurgy of welding, 5th edn. Chapman & Hall, London.
Lippold, J. C. and Kotecki, D. J. (2005). Welding metallurgy and weldability of stainless steel, New Jersey: WileyInterscience.
Lo, K.H., Shek, C.H. and Lai, J.K.L. (2009). Recent developments in stainless steels. Materials Science and
Engineering: R: Reports, 65(4-6): 39-104.
Morris Jr., J. W. (2001). The influence of grain size on the mechanical properties of steel. Retrieved on May 29,
2019. http://www.osti.gov/bridge/servlets/purl/861397-Tb7pb9/861397.pdf.
Mridha, S. and Baker, T.N. (1994). Crack-free hard surfaces produced by laser nitriding of commercial purity
titanium. Materials Science and Engineering A, 188(1-2): 229-239.
Mridha, S., Ong, H.S., Poh, L.S. and Cheang, P. (2001). Intermetallic coatings produced by TIG surface melting.
Journal of Materials Processing Technology, 113(1-3): 516-520.
Sarker, D. (2010). Hard coating layer formation on plain carbon steel surfaces by powder preplacement and TIG
torch melting techniques, unpublished, Masters Thesis, International Islamic University Malaysia, Gombak,
2010.
Shahid, Z., Muhammad, A., Khattak, M., and Nasir, T. (2018). Effects of welding on the microstructural properties
of AISI 430 ferritic stainless steel. Journal of Advanced Research in Materials Science, 44(1): 25-32.
Villafuerte, J.C., Pardo, E. and Kerr, H.W. (1990). The effect of alloy composition and welding conditions on
columnar-equiaxed transitions in ferritic stainless steel gas-tungsten arc welds. Metallurgical Transactions
A, 21(7): 2009 – 2019.
Published
2020-03-30
How to Cite
Amuda, M., Lawal, F., & Mridha, S. (2020). Microstructure Evolution in AISI 430 Ferritic Stainless Steel Welds Treated with Aluminum and Titanium Powder Mixture. Journal of Engineering Research, 25(1), 50-64. Retrieved from http://jer.unilag.edu.ng/article/view/982