Study on the Flow Field of Friction Stir Welding of AZ31 Magnesium Alloy Based on the Temperature Variation

Ali Lu; Sheng Lu; Shu Jin Chen; Dai Li Yang

doi:10.4028/www.scientific.net/MSF.789.282

Paper Titles

Fabrication of Polyvinylpyrrolidone/Boehmite Nanofibers by Electrospinning
p.259

The Effect of Bacterial Cellulose (BC) Fiber Content on the Properties of BC Fiber Reinforced Nanocomposites
p.262

Preparation and Study on Nano-Ag/SnO₂ Electrical Contact Material Doped Rare Earth Element
p.270

Effects of Cold Rolling Reduction on Deformation Modes in Mg-3Al-1Zn Magnesium Alloy
p.275

Study on the Flow Field of Friction Stir Welding of AZ31 Magnesium Alloy Based on the Temperature Variation
p.282

Effect of Brazing Flux Pb on Microstructure and Mechanical Property of CMT Weld-Brazed Lap Joint of 5052 Aluminum Alloy to Galvanized Q235 Steel
p.290

Influences of Carbon and Nitrogen Content on the Precipitation of 18Cr18Mn Steel
p.297

Study on Pack Rolling and Annealing Process for Ultra-Fined Grain Austenite Stainless Steel
p.303

Effect of Deformation Ratio on Microstructures and Properties of High Nitrogen Martensitic Stainless Steel
p.308

HomeMaterials Science ForumMaterials Science Forum Vol. 789Study on the Flow Field of Friction Stir Welding...

Study on the Flow Field of Friction Stir Welding of AZ31 Magnesium Alloy Based on the Temperature Variation

Abstract:

In this study, AZ31 magnesium alloy plates were butt welded by friction stir welding to investigate the flow field characterization, and temperature variation was measured. “Marker insert technology” and “stitch welding of dissimilar materials technique” were used to make the flow field visualization. The results indicated that both the temperature variation and the flow way of material are three dimensional asymmetric. In terms of temperature distribution, along the welding direction, the temperature is gradually increased during the process; along the thickness direction, the peak temperature is high in the upper part and low in the lower; perpendicular to the welding direction, the peak temperature of the advancing side is slightly higher than the retreating side. In terms of the flow field, the flow way of the material in the advancing side is different from retreating side. Material from the advancing side crosses the pin and is divided into two directions: part is dragged forward by the shoulder while part is extruded backward. However, materials in retreating side move backward only. At different depths, the flow range of plastic material is different. The closer to the bottom of the weld, the flow range of plastic material is smaller. Along the welding direction, the flow range of the plastic material changes larger from the initial stage to the end stage. On the cross section of the weld, plastic material that adjacent to the pin is squeezed down while part of the material at the bottom is forced to move upwards. The rising material converged with the downward current and formed a cycle. Considering the deformation tendency of the lapped surface, the advancing side is more intense than the retreating side.

You might also be interested in these eBooks

Nano-Scale Materials, Materials Processing and Genomic Engineering

View Preview

Info:

Periodical:

Materials Science Forum (Volume 789)

Pages:

282-289

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.789.282

Citation:

Cite this paper

Online since:

April 2014

Authors:

Ali Lu*, Sheng Lu, Shu Jin Chen, Dai Li Yang

Keywords:

Flow Field, Friction Stir Welding (FSW), Overlay Welding of Dissimilar Materials, Tags Embedded Technology, Temperature Distribution

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] W. B. Wang, W. Wang, D. L. Wang et al. Analysis on the temperature field of Aluminum alloy in the initial state of friction stir welding [J]. Hot Working Technology, 2008, 37(21):107-109,113.

Google Scholar

[2] H. Zhang, S. B. Lin, L. Wu et al. Numerical simulation of the temperature field of friction stir welding of AZ31 magnesium alloy [J]. Aerospace Materials & Technology, 2004, 34(6):58-61.

Google Scholar

[3] X. J. Wang, X. H. Han, R. J. Guo et al. Numerical simulation of the temperature field of friction stir welding [J]. Journal of welding, 2005, 26(12):17-20.

Google Scholar

[4] M. Guerra, C. Schmidt, J. C. McClure et al. Flow pattern during Friction Stir Welding [J]. Materials Characterization, 2003, 49:95s-101s.

Google Scholar

[5] K. Colligan. Material flow behavior during Friction Stir Welding of Aluminum [J].Welding Journal, 1999, 78(7):229s-237s.

Google Scholar

[6] W. Zhang, N. M. Ke, L. Xing et al. Analysis of the transfer behavior of material on cross-section of friction stir welding [J]. Materials engineering, 2008, (2):62-66.

Google Scholar

[7] T. U. Seidel, A. P. Reynolds. A two-dimensional Friction Stir Welding Process Model Based on Fluid Mechanics [J].Science and Technology of Welding and Joining, 2003, 8:175s-183s.

DOI: 10.1179/136217103225010952

Google Scholar

[8] X. J. Wang, X. H. Han, C. F. Li et al. The study on the flow of plastic material in different depth of thick aluminum plates along the horizontal direction [J]. Chinese Journal of nonferrous metals, 2005, 15(2):198-204.

Google Scholar

[9] X. J. Wang, X. H. Han, C. F. Li et al. The study on the flow of plastic material in different depth of thick aluminum plates along the thickness direction [C].2004 The International Forum on aerospace welding technology.2004:328-333.

Google Scholar

[10] X. J. Wang, X. H. Han. Three dimension numerical simulation of friction stir welding of aluminum alloy based on fluent [J]. Electric Welding Machine, 2006, 36(1):48-50.

Google Scholar

[11] X. H. Han, X. J. Wang. Flow field of friction stir welding of aluminum alloy along the thickness direction [J]. Electric Welding Machine, 2006, 36(11):48-52.

Google Scholar

[12] X. H. Han, X. J. Wang. Flow field of friction stir welding of aluminum alloy along the horizontal direction [J]. Electric Welding Machine, 2006, 36(3):52-54.

Google Scholar

[13] M. Xiao. Research on the microstructure and thermal deformation behavior of the AZ31 magnesium alloy [D]. Dissertation of master degree of Chongqing University.2009:27-48.

Google Scholar