Experimental characterization of Ti6Al4V T joints welded through linear friction welding technique: microstructure and NDE

Antonello Astarita, Mario Coppola, Sergio Esposito, Mariacira Liberini, Leandro Maio, Ilaria Papa, Fabio Scherillo, Antonino Squillace

Advances in Manufacturing ›› 2016, Vol. 4 ›› Issue (4) : 305-313.

Advances in Manufacturing ›› 2016, Vol. 4 ›› Issue (4) : 305-313. DOI: 10.1007/s40436-016-0160-7
Article

Experimental characterization of Ti6Al4V T joints welded through linear friction welding technique: microstructure and NDE

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Abstract

Linear friction welding (LFW) is an innovative solid-state welding technique that allows to manufacture joints with high mechanical properties. This technology has various applications in the aerospace field; in particular it is used to weld massive structural components made of Ti6Al4V. This paper deals with the experimental study of Ti6Al4V T-joints welded through LFW, with particular focus on the effectiveness of ultrasonic control in detecting and distinguishing welding defects within the joints. Aiming to this scope, joints with different properties were manufactured and tested: some were free from defects but with different metallurgy, and some had different types of defects. The results obtained proved that the ultrasonic control was an effective method to detect and identify defects in linear friction welded titanium joints, moreover it was possible to get information regarding the microstructure and in particular the extension of the different metallurgical zones induced by the welding process.

Keywords

Ti6Al4V / Ultrasonic control / Linear friction welding (LFW) / Microstructure / Defects

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Antonello Astarita, Mario Coppola, Sergio Esposito, Mariacira Liberini, Leandro Maio, Ilaria Papa, Fabio Scherillo, Antonino Squillace. Experimental characterization of Ti6Al4V T joints welded through linear friction welding technique: microstructure and NDE. Advances in Manufacturing, 2016, 4(4): 305‒313 https://doi.org/10.1007/s40436-016-0160-7

References

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[1.]
Zhao P, Fu L, Chen H. Low cycle fatigue properties of linear friction welded joint of TC11 and TC17 titanium alloys. J Alloy Compd, 2016, 675: 248-256.
CrossRef Google scholar
[2.]
Wang SQ, Ma TJ, Li WY, et al. Microstructure and fatigue properties of linear friction welded TC4 titanium alloy joints. Sci Technol Weld Join, 2016, 2: 1-5.
[3.]
Astarita A, Scherillo F, Curioni M, et al. Study of the linear friction welding process of dissimilar Ti-6Al-4V—stainless steel joints. Mater Manuf Process, 2016
[4.]
Ji Y, Zhang T, Guo D, et al. Structure and mechanical property of DD6/FGH96 linear friction welding joint. Hanjie Xuebao/Trans China Weld Inst, 2016, 37(4): 111-114.
[5.]
Chen X, Xie FQ, Ma TJ, et al. Effects of post-weld heat treatment on microstructure and mechanical properties of linear friction welded Ti2AlNb alloy. Mater Des, 2016, 94: 45-53.
[6.]
Vairis A. Linear and rotary friction welding review. Int Mater Rev, 2010.
[7.]
Ma TJ, Chen X, Li WY, et al. Microstructure and mechanical property of linear friction welded nickel-based superalloy joint. Mater Des, 2016, 89: 85-93.
[8.]
Zhang CC, Zhang TC, Ji YJ, et al. Formation process and mechanism of linear friction welding joint. J Mater Eng, 2015, 43(11): 39-43.
[9.]
Vairis A, Frost M. High frequency linear friction welding of a titanium alloy. Wear, 1998, 217(1): 117-131.
CrossRef Google scholar
[10.]
Rao HM, Ghaffari B, Yuan W, et al. Effect of process parameters on microstructure and mechanical behaviors of friction stir linear welded aluminum to magnesium. Mater Sci Eng A, 2016, 651: 27-36.
CrossRef Google scholar
[11.]
Buffa G, Cammalleri M, Campanella D, et al. Linear friction welding of dissimilar AA6082 and AA2011 aluminum alloys: microstructural characterization and design guidelines. Int J Mater Form, 2015, 22: 1-9.
[12.]
Impero F, Scherillo F, Astarita A, et al. Study of the metallurgy of dissimilar Ti-6Al-4V-stainless steel linear fiction welded joints. Key Eng Mater, 2015, 651–653: 1427-1432.
CrossRef Google scholar
[13.]
Bhamji I, Preuss M, Threadgill PL, et al. Linear friction welding of AISI 316L stainless steel. Mater Sci Eng A, 2010, 528: 680.
CrossRef Google scholar
[14.]
Karadge M, Preuss M, Lovell C, et al. Texture development in Ti-6Al-4V linear friction welds. Mater Sci Eng A, 2007, 459: 182-191.
CrossRef Google scholar
[15.]
Ma Tiejun, Chen Tao, Wen Y. Formation mechanism of linear friction welded Ti-6Al-4V alloy joint based on microstructure observation. Mater Charact, 2011, 62: 130-135.
CrossRef Google scholar
[16.]
Li B, Shen Y, Hu W. The study on defects in aluminum 2219-T6 thick butt friction stir welds with the application of multiple non-destructive testing methods. Mater Des, 2011, 32: 2073-2084.
CrossRef Google scholar
[17.]
Chen C, Kovacevic R, Jandgric D. Wavelet transform analysis of acoustic emission in monitoring friction stir welding of 6061 aluminum. Int J Mach Tools Manuf, 2003, 43: 1383-1390.
CrossRef Google scholar
[18.]
Akinlabi ET, Levy ACS, Akinlabi SA (2012) Non-destructive testing of dissimilar friction stir welds. In: proceedings of the world congress on engineering, 4–6 July, London
[19.]
Hu B, Yu R, Zou H. Magnetic non-destructive testing method for thin-plate aluminum alloys. NDT E Int, 2012, 47: 66-69.
CrossRef Google scholar
[20.]
Guo X, Vavilov V. Crack detection in aluminum parts by using ultrasound-excited infrared thermography. Infrared Phys Technol, 2013, 61: 149-156.
CrossRef Google scholar
[21.]
Leonard AJ, Lockyer SA (2003) Flaws in friction stir welds. In: proceedings of the 4th international symposium friction stir welding, 14–16 May, Park City, Utah, 2003
[22.]
Saravanan T, Lahiri BB, Arunmuthu K, et al. Non-destructive evaluation of friction stir welded joints by X-ray radiography and infrared thermography. Proc Eng, 2014, 86: 469-475.
CrossRef Google scholar
[23.]
Kumar A, Philip J (2011) Defect detection in weld joints by infrared thermography. In: proceedings of international conference on NDE steel allied industries, NDESAI Jamshedpur, 2011, pp 191–198
[24.]
Harper M, Hallmark TS, Andrew ME, et al. A comparison of X-ray fluorescence and wet chemical analysis of air filter samples from a scrap lead smelting operation. J Environ Monit, 2004, 6(10): 819-826.
CrossRef Google scholar
[25.]
Rosado-Mendez IM, Hall TJ, Zagzebski JA (2014) Pulse-echo sound speed estimation based on a Nakagami model of the echo amplitude. In: IEEE international ultrasonics symposium, pp 2442–2445
[26.]
Santos TG, Vilaça P, Rosa do L et al (2010) Developments in NDT of friction stir welding. 10 th ECNDT, Moscow
[27.]
Lamarre A, Dupuis O, Moles M (2004) Complete inspection of friction stir welds in aluminum using ultrasonic and eddy current arrays. 16th WCNDT, Montreal
[28.]
Hedin A, Carlson L, Borg M (2008) Defect detection by laser-ultrasonics in friction stir welded joints in aluminium pro files. In: Proceedings of the 1st international symposium on laser ultrasonics: science, technology and applications. 16–18 July, Montreal
[29.]
Lévesque D, Dubourg L, Blouin A. Laser ultrasonics for defect detection and residual stress measurement of friction stir welds. Non Destruct Test Eval, 2011, 26: 319-333.
CrossRef Google scholar
[30.]
Astarita A, Curioni M, Squillace A, et al. Corrosion behaviour of stainless steel–titanium alloy linear friction welded joints: Galvanic coupling. Mater Corros, 2015, 66: 111-117.
CrossRef Google scholar
[31.]
Boyer R, Collings EW, Welsch G (eds) (1993) Materials properties handbook: titanium alloys. ASM International, Materials Park
[32.]
Wanjara P, Jahazi M. Linear friction welding of Ti-6Al-4V: processing, microstructure, and mechanical-property inter-relationships. Metall Mater Trans A, 2005, 36(8): 2149-2164.
CrossRef Google scholar
[33.]
Bhamji I, Preuss M, Threadgill PL, et al. Solid state joining of metals by linear friction welding: a literature review. Mater Sci Technol, 2011, 27(1): 2-12.
CrossRef Google scholar
[34.]
Grujicic M, Arakere G, Pandurangan B, et al. Process modeling of Ti-6Al-4V linear friction welding (LFW). J Mater Eng Perform, 2012, 21(10): 2011-2023.
CrossRef Google scholar
[35.]
Scarponi C, Valente M. An application of a new ultrasonic technique to jute composite laminates subjected to low-velocity impact. Int J Mater Prod Technol, 2006, 26(1–2): 6-16.
CrossRef Google scholar
[36.]
Busse G. Optoacoustic phase angle measurement for probing a metal Appl. Phys Lett, 1979, 35: 759-760.
[37.]
Carlone P, Palazzo GS. Influence of process parameters on microstructure and mechanical properties in AA2024-T3 friction stir welding. Metallogr Microstruct Anal, 2013, 2(4): 213-222.
CrossRef Google scholar
[38.]
Cahn R, Haasen P (1996) Physical metallurgy, 4th edn. Elsevier, New York
[39.]
Burke J, Turnbull D. Recrystallization and grain growth. Prog Metal Phys, 1952, 3: 220-292.
CrossRef Google scholar

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