Investigation of Residual Stresses Distribution in Titanium Weldments-Reference-Cited by-同舟云学术

Investigation of Residual Stresses Distribution in Titanium Weldments

Published:2014-02 Issue: Volume:777 Page:171-175
ISSN:1662-9752
Container-title:Materials Science Forum
language:
Short-container-title:MSF

Author:

Song Shao Pin¹,Paradowska Anna M.²,Dong Ping Sha¹

Affiliation:

1. University of New Orleans

2. Australian Nuclear Science and Technology Organisation

Abstract

Titanium and its alloys have increasingly become a material of choice for applications in high-performance structures due to their superior corrosion resistance and high strength-to-weight ratio. However, in contrast to conventional steel alloys, there exist little design and manufacturing experience in the heavy fabrication industry with large welded structures made of titanium materials. In addressing the above concern, the University of New Orleans funded by Office of Naval Research (ONR) initiated program on investigation of manufacturability and performance of a titanium mid-ship section. The uniqueness of this program is its focus upon a representative full-size mid-ship section upon which relevant scientific and technological challenges are simulated and experimentally validated. This paper reports the measurements of residual stresses using neutron diffraction in titanium T-joints. The residual stresses were measured using Engin-X at ISIS (UK) and the Kowari Strain Scanner at ANSTO (Australia). This experimental research was used to validate our in house predictions and significantly improved the knowledge and understanding of the welding process of titanium alloys.

Publisher

Trans Tech Publications, Ltd.

Subject

Mechanical Engineering,Mechanics of Materials,Condensed Matter Physics,General Materials Science

Link

https://www.scientific.net/MSF.777.171.pdf

Reference9 articles.

1. P. Dong, C. NIE, X. Yang, S. Song, L. DeCan, A math-based design-for-produceability evaluation of titanium applications in ship hull structures, Ship Production Symposium, 2011 SNAME Annual Meeting, Houston, Texas, USA.

2. T.D. Huang, C. Conrardy, P. Dong, P. Keene, L. Kvidahl, L. DeCan, Engineering and production technology for lightweight ship structures, Part II: distortion mitigation technique and implementation, Journal of Ship Production, 23 (2007) 82-93.

3. G. Bruno, B.D. Dunn, Surface and bulk residual stress in Ti6Al4V welded aerospace tanks, J. Press. Vessel Technol. 126 (2004) 284-291.

4. J.R. Cho, K.T. Conlon, R.C. Reed, Residual stress in an electron beam weld of Ti-834: characterization and numerical modeling, Metall. Mater. Trans. A, 34A (2003) 2935-2946.

5. M. Grujicic, G. Arakere, B. pandurangan, A. Hariharan, B.A. Cheeseman, C-F. Yen, C. Fountzoulas, Computational analysis and experimental validation of the Ti-6Al-4V friction stir welding behavior, Clemson University, (2010).

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