Abstract
This work focuses on the microstructural characterization of aluminum to steel friction stir welded joints. Lap weld configuration coupled with scribe technology used for the weld tool have produced joints of adequate quality, despite the significant differences in hardness and melting temperatures of the alloys. Common to friction stir processes, especially those of dissimilar alloys, are microstructural gradients including grain size, crystallographic texture, and precipitation of intermetallic compounds. Because of the significant influence that intermetallic compound formation has on mechanical and ballistic behavior, the characterization of the specific intermetallic phases and the degree to which they are formed in the weld microstructure is critical to predicting weld performance. This study used electron backscatter diffraction, energy dispersive spectroscopy, scanning electron microscopy, and Vickers micro-hardness indentation to explore and characterize the microstructures of lap friction stir welds between an applique 6061-T6 aluminum armor plate alloy and a RHA homogeneous armor plate steel alloy. Macroscopic defects such as micro-cracks were observed in the cross-sectional samples, and binary intermetallic compound layers were found to exist at the aluminum-steel interfaces of the steel particles stirred into the aluminum weld matrix and across the interfaces of the weld joints. Energy dispersive spectroscopy chemical analysis identified the intermetallic layer as monoclinic Al3Fe. Dramatic decreases in grain size in the thermo-mechanically affected zones and weld zones that evidenced grain refinement through plastic deformation and recrystallization. Crystallographic grain orientation and texture were examined using electron backscatter diffraction. Striated regions in the orientations of the aluminum alloy were determined to be the result of the severe deformation induced by the complex weld tool geometry. Many of the textures observed in the weld zone and thermo-mechanically affected zones exhibited shear texture components; however, there were many textures that deviated from ideal simple shear. Factors affecting the microstructure which are characteristic of the friction stir welding process, such as post-recrystallization deformation and complex deformation induced by tool geometry were discussed as causes for deviation from simple shear textures.
Similar content being viewed by others
Abbreviations
- BM:
-
Base metal
- BCC:
-
Body-centered cubic
- BCT:
-
Body-centered tetragonal
- CDRX:
-
Continuous dynamic recrystallization
- EBSD:
-
Electron backscatter diffraction
- EDS:
-
Energy dispersive spectroscopy
- FCC:
-
Face-centered cubic
- FE-SEM:
-
Field emission scanning electron microscope
- FSS:
-
Friction stir scribe
- FSW:
-
Friction stir welding
- HAZ:
-
Heat-affected zone
- HSLA:
-
High-strength low alloy
- HABs:
-
High-angle boundaries
- IMCs:
-
Intermetallic compounds
- LABs:
-
Low-angle boundaries
- ND:
-
Normal direction
- PNNL:
-
Pacific Northwest National Laboratory
- PP :
-
Point-per-point
- PF:
-
Pole figure
- RD:
-
Rolling direction
- SEM:
-
Scanning electron microscopy
- SD:
-
Shear direction
- SPN:
-
Shear plane normal
- TMAZ:
-
Thermo-mechanically affected zone
- TD:
-
Transverse direction
- V Fe :
-
Volume fraction of steel particles
- WD:
-
Weld direction
- WZ:
-
Weld zone
References
K. Kimapong, T. Watanabe. Weld J (2004) 83: 277–82.
R. Johnson and P.L. Threadgill: Progress in Friction Stir Welding Of Aluminum and Steel for Marine Applications. TWI: Published Papers. October, 2013. http://www.twi.co.uk/technical-knowledge/published-papers/progress-in-friction-stir-welding-of-aluminium-and-steel-for-marine-applications-october-2003/. Accessed 21 May 2013.
H. Uzun, C.D. Donne, A. Argagnotto, T. Ghidini, C. Gambaro. Mater Design 26 (2005) 41-46.
R.M. Leal, A. Loureiro. Mater Design 29 (2008) 982-991.
S. Xu, X. Deng. Acta Mater 56 (2008) 1326-1341.
J. Young, D. Field, T. Nelson. Metall Mater Trans A 44, 7 (2013) 3167-75.
M.A. Sutton, B. Yang, A.P. Reynolds, R. Taylor. Mater Sci Eng A 323 (2002) 160-66.
D.A. Wang, S.C. Lee. J Mater Process Tech 186 (2007) 291-297.
A.A.M. da Silva, E. Arruti, G. Janeiro, E. Aldanondo, P. Alvarez, A. Echeverria. Mater Design 32 (2011) 2021-27.
S.J. Kalita. Appl Surf Sci 257 (2011) 3985-97.
M.A. Sutton, A.P. Reynolds, B. Yang, R. Taylor. Mater Sci Eng A 354 (2003) 6-16.
D.A. Wang, C.H. Chen. “Fatigue lives of friction stir spot welds in aluminum 6061-T6 sheets.” J Mater Process Tech 209 (2009) 367-375.
M.B. Prime, T. Gnäupel-Herold, J.A. Baumann, R.J.Lederich, D.M. Bowden, R.J. Sebring. Acta Mater 54 (2006) 4013-4021.
V-X. Tran, J. Pan. “Fatigue behavior of dissimilar spot friction welds in lap-shear and cross-tension specimens of aluminum and steel sheets.” Int J Fatigue 32 (2010) 1167–79.
T. Tanaka, T. Morishige, T. Hirata. Scr. Mater 61 (2009) 756–59.
S. Jana, Y. Hovanski. “Fatigue behaviour of magnesium to steel dissimilar friction stir lap joints.” Sci Technol Weld Joi 17 (2012) 141-145.
H.-H. Cho, S.H. Kang, S.-H. Kim, K.H. Oh, H.J. Kim, W.-S. Chang, H.N. Han. “Microstructural evolution ahead in friction stir welding of high-strength linepipe steel.” Mater Design 34 (2012) 258-267.
S. Jana, Y. Hovanski, G.J. Grant. “Friction stir lap welding of magnesium alloy to steel: A preliminary investigation.” Metall Mater Trans A 41A (2010) 3173-3182.
S. Jana, Y. Hovanski, G.J. Grant, K. Mattlin: Effect of Tool Feature on the Joint Strength of Dissimilar Friction Stir Lap Welds. TMS International Conference Proceedings. 2011.
W.H. Jiang, R. Kovacevic: Proc. Inst. Mech Eng B 218 (2004):1323-31
T. Watanabe, H. Takayama, A. Yanagisawa. “Joining of aluminum alloy to steel by friction stir welding.” J Mater Process Tech 178 (2006) 342–49.
W-B Lee, M. Schmuecker, U.A. Mercardo, G. Biallas, S-B Jung. “Interfacial reaction in steel-aluminum joints made by friction stir welding.” Scripta Mater 55 (2006) 355-358.
M. Movahedi, A.H. Kokabi, S.M. Seyed Reihani, W.J. Cheng, C.J. Wang. Mater Des. (2012), doi: 10.1016/j.matdes.2012.08.028
R.W. Fonda, J.F. Bingert. “Texture variations in an aluminum friction stir weld.” Scripta Mater 57 (2007) 1052-1055.
R.W. Fonda, J.F. Bingert, K.J. Colligan. “Development of grain structure during friction stir welding.” Scripta Mater 51 (2004) 243-248.
D.P. Field, T.W. Nelson, Y. Hovanski, K.V. Jata. “Heterogeneity of crystallographic texture in friction stir welds of aluminum.” Metall Mater Trans A 32 (2001) 2869-2867.
U.F. Kocks, C.N. Tomé, H.-R. Wenk. Texture and Anisotropy: Preferred Orientations in Polycrystals and their Effect on Materials Properties. Cambridge: Cambridge University Press. 2000.
Z.Y. Ma, R.S. Mishra, M.W. Mahoney. “Superplastic deformation behavior of friction stir processed 7075 Al alloy.” Acta Mater 50 (2002) 4419-4430.
C.G. Rhodes, M.W. Mahoney, W.H. Bingel, M. Calabrese. “Fine-grain evolution in friction stir processed 7050 aluminum.” Scripta Mater 48 (2003) 1451-1455.
S. Gourdet, F. Montheillet. “A model of continuous dynamic recrystallization.” Acta Mater 51 (2003) 2685-2699.
Y.S. Sato, T.W. Nelson, C.J. Sterling, R.J. Steel, C.-O. Pettersson. “Microstructure and mechanical properties of friction stir welded SAF 2507 super duplex stainless steel.” Mater Sci Eng A 397 (2005) 376-384.
H.G. Salem, A.P. Reynolds, J.S. Lyons. “Microstructure and retention of superplasticity of friction stir welded superplastic 2095 sheet.” Scripta Mater 46 (2002) 337-342.
J.C. Russ. Practical Stereology 2nd ed. New York: Plenum Press. 1999.
Y.-C. Chen, D. Bakavos, A. Gholinia, P.B. Pragnell. “HAZ development and accelerated post-weld natural ageing in ultrasonic spot welding aluminium 6111-T4 automotive sheet.” Acta Mater 60 (2012) 2816-2828.
S.J. Unfried, C.M. Garzón, J.E. Giraldo. J Mater Process Tech 209 (2009) 1688-1700.
Acknowledgments
Funding for this project was provided by the United States Army Tank Automotive Research, Development, and Engineering Center via subcontract with Pacific Northwest National Laboratory. The insight of Dr. Nathaniel Sanchez and Dr. John Young on mechanical polishing of aluminum and dissimilar alloy specimens for EBSD is gratefully acknowledged.
Author information
Authors and Affiliations
Corresponding author
Additional information
Manuscript submitted August 26, 2014.
Manuscript Authored by Battelle Memorial Institute Under Contract Number DE·AC05-76RL01830 with the US Department of Energy. The US Government retains and the publisher, by accepting this article for publication, acknowledges that the US Government retains a non-exclusive, paid-up, irrevocable, world-wide license to publish or reproduce the published form of this manuscript, or allow others to do so for US Government purposes. The Department of Energy will provide public access to these results of federally sponsored research in accordance with the DOE Public Access Plan: (http://energy.gov/downloads/doe-public-access-plan).
Rights and permissions
About this article
Cite this article
Patterson, E.E., Hovanski, Y. & Field, D.P. Microstructural Characterization of Friction Stir Welded Aluminum-Steel Joints. Metall Mater Trans A 47, 2815–2829 (2016). https://doi.org/10.1007/s11661-016-3428-4
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11661-016-3428-4