In this study, the microstructure, substructure and hardness of the friction stir welded Monel 400 were investigated and compared with those of the base metal. For this purpose, the Monel 400 plates were friction stir welded at a tool rotational speed of 400 rpm, and a tool traverse speed of 100 mm/min. For characterizing the microstructure and grain boundaries in base metal and stir zone, the electron backscattered diffraction was utilized. The transmission electron microscopy was used for studying the substructures. In addition, microhardness test was conducted to hardness measurement. The results showed that the grain refinement, increasing in dislocation density and Taylor factor were the main reasons of the higher hardness of the stir zone.
Song, K.H., Chung, Y.D. and Nakata, K., "Investigation of microstructure and mechanical properties of friction stir lap jointed Monel 400 and Inconel 600", Metals and Materials International, Vol. 19, pp. 571-576, (2013).
Singh, V.B. and Gupta, A., "The electrochemical corrosion and passivation behaviour of Monel (400) in concentrated acids and their mixtures", Journal of Materials Science, Vol. 36, pp. 1433-1442, (2001).
Ojo, O.A., Richards, N.L. and Chaturvedi, M.C., "Contribution of constitutional liquation of gamma prime precipitate to weld HAZ cracking of cast Inconel 738 superalloy", Scripta Materialia, Vol. 50, pp. 641-646, (2004).
Huang, C.A., Wang, T.H., Han, W.C. and Lee, C.H., "A study of the galvanic corrosion behavior of Inconel 718 after electron beam welding", Materials Chemistry and Physics, Vol. 104, pp. 293-300, (2007).
Kim, J.-D., Kim, C.-J. and Chung, C.-M., "Repair welding of etched tubular components of nuclear power plant by Nd:YAG laser", Journal of Materials Processing Technology, Vol. 114, pp. 51-56, (2001).
Mishra, R.S. and Ma, Z.Y., "Friction stir welding and processing", Materials Science and Engineering: R: Reports, Vol. 50, pp. 1-78, (2005).
Amirafshar, A. and Pouraliakbar, H., "Effect of tool pin design on the microstructural evolutions and tribological characteristics of friction stir processed structural steel", Measurement, Vol. 68, pp. 111-116, (2015).
Golezani, A.S., Barenji, R.V., Heidarzadeh, A. and Pouraliakbar, H., "Elucidating of tool rotational speed in friction stir welding of 7020-T6 aluminum alloy", The International Journal of Advanced Manufacturing Technology, Vol. 81, pp. 1155-1164, (2015).
Asadi, P., Akbari, M., Besharati Givi, M.K. and Shariat Panahi, M., "Optimization of AZ91 friction stir welding parameters using Taguchi method", Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications, Vol. 230, pp. 291-302, (2015).
Asadi, P., Besharati Givi, M.K. and Akbari, M., "Simulation of dynamic recrystallization process during friction stir welding of AZ91 magnesium alloy", The International Journal of Advanced Manufacturing Technology, Vol. 83, pp. 301-311, (2016).
Heidarzadeh, A., Khodaverdizadeh, H., Mahmoudi, A. and Nazari, E., "Tensile behavior of friction stir welded AA 6061-T4 aluminum alloy joints", Materials & Design, Vol. 37, pp. 166-173, (2012).
Heidarzadeh, A. and Saeid, T., "A comparative study of microstructure and mechanical properties between friction stir welded single and double phase brass alloys", Materials Science and Engineering: A, Vol. 649, pp. 349-358, (2016).
Heidarzadeh, A. and Saeid, T., "Correlation between process parameters, grain size and hardness of friction-stir-welded Cu–Zn alloys", Rare Metals, Vol. pp. 1-11, (2016).
Heidarzadeh, A., Saeid, T. and Klemm, V., "Microstructure, texture, and mechanical properties of friction stir welded commercial brass alloy", Materials Characterization, Vol. 119, pp. 84-91, (2016).
Etter, A.L., Baudin, T., Fredj, N. and Penelle, R., "Recrystallization mechanisms in 5251 H14 and 5251 O aluminum friction stir welds", Materials Science and Engineering: A, Vol. 445–446, pp. 94-99, (2007).
Fonda, R.W., Bingert, J.F. and Colligan, K.J., "Development of grain structure during friction stir welding", Scripta Materialia, Vol. 51, pp. 243-248, (2004).
Ghosh, M., Kumar, K. and Mishra, R.S., "Analysis of microstructural evolution during friction stir welding of ultrahigh-strength steel", Scripta Materialia, Vol. 63, pp. 851-854, (2010).
Miura *, H., Sakai, T., Andiarwanto, S. and Jonas, J.J., "Nucleation of dynamic recrystallization at triple junctions in polycrystalline copper", Philosophical Magazine, Vol. 85, pp. 2653-2669, (2005).
Miura, H., Aoyama, H. and Sakai, T., "Effect of Grain-Boundary Misorientation on Dynamic Recrystallization of Cu-Si Bicrystals", Journal of the Japan Institute of Metals, Vol. 58, pp. 267-275, (1994).
Sakai, T., Belyakov, A., Kaibyshev, R., Miura, H. and Jonas, J.J., "Dynamic and post-dynamic recrystallization under hot, cold and severe plastic deformation conditions", Progress in Materials Science, Vol. 60, pp. 130-207, (2014).
Starink, M.J., Deschamps, A. and Wang, S.C., "The strength of friction stir welded and friction stir processed aluminium alloys", Scripta Materialia, Vol. 58, pp. 377-382, (2008).
Starink, M.J. and Wang, S.C., "A model for the yield strength of overaged Al–Zn–Mg–Cu alloys", Acta Materialia, Vol. 51, pp. 5131-5150, (2003).
Xue, Z., Huang, Y. and Li, M., "Particle size effect in metallic materials: a study by the theory of mechanism-based strain gradient plasticity", Acta Materialia, Vol. 50, pp. 149-160, (2002).
Wang, S., Zhu, Z. and Starink, M., "Estimation of dislocation densities in cold rolled Al‐Mg‐Cu‐Mn alloys by combination of yield strength data, EBSD and strength models", Journal of microscopy, Vol. 217, pp. 174-178, (2005).
Heidarzadeh, A. (2020). Friction Stir Welding of Monel 400: Microstructure, Substructure, and Mechanical Properties. Journal Of Metallurgical and Materials Engineering, 31(2), 45-56. doi: 10.22067/ma.v31i2.68236
MLA
Akbar Heidarzadeh. "Friction Stir Welding of Monel 400: Microstructure, Substructure, and Mechanical Properties", Journal Of Metallurgical and Materials Engineering, 31, 2, 2020, 45-56. doi: 10.22067/ma.v31i2.68236
HARVARD
Heidarzadeh, A. (2020). 'Friction Stir Welding of Monel 400: Microstructure, Substructure, and Mechanical Properties', Journal Of Metallurgical and Materials Engineering, 31(2), pp. 45-56. doi: 10.22067/ma.v31i2.68236
CHICAGO
A. Heidarzadeh, "Friction Stir Welding of Monel 400: Microstructure, Substructure, and Mechanical Properties," Journal Of Metallurgical and Materials Engineering, 31 2 (2020): 45-56, doi: 10.22067/ma.v31i2.68236
VANCOUVER
Heidarzadeh, A. Friction Stir Welding of Monel 400: Microstructure, Substructure, and Mechanical Properties. Journal Of Metallurgical and Materials Engineering, 2020; 31(2): 45-56. doi: 10.22067/ma.v31i2.68236
Send comment about this article