Numerical Simulation of Ti/Al Dissimilar Friction Stir Welding and Prediction of Intermetallic Compound Layer Evolution

doi:10.3901/JME.2024.22.106

Abstract

Abstract: Friction stir welding(FSW) is highly suitable for the fabrication of Ti/Al structures. However, the effects of process parameters on mass and heat transfer during the FSW of Ti/Al joints, as well as the precise control of interfacial intermetallic compounds(IMCs), still require further investigation. This study, based on fluid dynamics and solid-state diffusion theory, simulates and compares the temperature fields, material flow, and IMCs growth in Ti/Al FSW under different welding speeds. The findings indicate that changes in welding speed have a smaller impact on the peak temperature during the FSW process than on the duration of high-temperature exposure. The model shows that at a welding speed of 15 mm/min, the high-temperature duration is approximately four times longer than at 60 mm/min, although the peak temperature difference at the interface between the two conditions is only about 40 K. The growth of IMCs is primarily influenced by the peak temperature and the duration of high-temperature exposure, with the latter being the main factor for thicker IMCs layers under lower welding speeds. At higher welding speeds, insufficient material flow at the bottom of the weld is the root cause of lack of penetration. The accuracy of the model is validated through experimental temperature measurements, TMAZ boundary assessment, and IMC thickness measurements.

Key words: aluminum/titanium dissimilar friction stir welding, temperature field, computational fluid dynamics model, solid phase diffusion theory, intermetallic compounds

CLC Number:

TG456

ZHANG Xiankun, SHI Lei, WU Chuansong, LIU Xiaochao, GAO Song. Numerical Simulation of Ti/Al Dissimilar Friction Stir Welding and Prediction of Intermetallic Compound Layer Evolution[J]. Journal of Mechanical Engineering, 2024, 60(22): 106-115.

References

[1] GADAKH V S，BADHEKA V J，MULAY A S. Solid-state joining of aluminum to titanium：A review[J]. Proceedings of the Institution of Mechanical Engineers, Part L：Journal of Materials：Design and Applications，2021，235(8)：1757-1799.
[2] MA Z，JIN Y，JI S，et al. A general strategy for the reliable joining of Al/Ti dissimilar alloys via ultrasonic assisted friction stir welding[J]. Journal of Materials Science & Technology，2019，35(1)：94-99.
[3] YU M，ZHAO H，XU F，et al. Effect of rotational speed on microstructure and mechanical properties of Al-Ti friction stir welds with ultrasonic vibrations[J]. Journal of Materials Processing Technology，2023，320：118119.
[4] 杨夏炜，孟廷曦，褚强，等. 铝合金双面搅拌摩擦焊接的研究进展[J]. 机械工程学报，2024，60(14)：77-96. YANG Xiawei，MENG Tingxi，CHU Qiang，et al. Research progress in double-sided friction stir welding of aluminum alloy[J]. Journal of Mechanical Engineering 2024，60(14)：77-96.
[5] MISHRA R S，MA Z Y. Friction stir welding and processing[J]. Materials Science and Engineering：R：Reports，2005，50(1)：1-78.
[6] 武传松，吕学奇，宿浩，等. 铝-镁异质合金搅拌摩擦焊接成形的研究进展[J]. 机械工程学报，2020，56(6)：4-16. WU Chuansong，LÜ Xueqi，SU Hao，et al. Research progress in dissimilar friction stir welding of aluminium/ magnesium alloys[J]. Journal of Mechanical Engineering，2020，56(6)：4-16.
[7] LI Y，SHI L，WU C，et al. Elucidation of welding speed on the microstructure and mechanical properties of medium-thick dissimilar Al/Ti double-side friction stir welded joint[J]. Materials Characterization，2023，200：112910.
[8] LI Y，ZHANG X，SHI L，et al. Double side friction stir Z shape butt lap welding of dissimilar titanium aluminum alloys[J]. International Journal of Mechanical Sciences，2024，271：109135.
[9] PEREIRA V F，FONSECA E B，COSTA A M S，et al. Nanocrystalline structural layer acts as interfacial bond in Ti/Al dissimilar joints produced by friction stir welding in power control mode[J]. Scripta Materialia，2020，174：80-86.
[10] SONG Z，NAKATA K，WU A，et al. Influence of probe offset distance on interfacial microstructure and mechanical properties of friction stir butt welded joint of Ti6Al4V and A6061 dissimilar alloys[J]. Materials & Design，2014，57：269-278.
[11] 翟明，武传松. 搅拌头/工件界面峰值温度的测量及预测[J]. 机械工程学报，2021，57(4)：36-43. ZHAI Ming，WU Chuansong. Tool/workpiece interface temperature measurement and prediction[J]. Journal of Mechanical Engineering，2021，57(4)：36-43.
[12] CHEN S，HAN Y，JIANG X，et al. Study on in-situ material flow behaviour during friction stir welding via a novel material tracing technology[J]. Journal of Materials Processing Technology，2021，297：117205.
[13] LIU X，WU C，PADHY G K. Characterization of plastic deformation and material flow in ultrasonic vibration enhanced friction stir welding[J]. Scripta Materialia，2015，102：95-98.
[14] 甄云乾，刘小超，申志康，等. 搅拌摩擦焊材料流动的试验表征研究现状[J]. 机械工程学报，2020，56(6)：184-192. ZHEN Yunqian，LIU Xiaochao，SHEN Zhikang，et al. State-of-art of experimental characterization of material flow in friction stir welding[J]. Journal of Mechanical Engineering，2020，56(6)：184-192.
[15] 陈高强，史清宇. 搅拌摩擦焊中材料流动行为数值模拟的研究进展[J]. 机械工程学报，2015，51(22)：11-21. CHEN Gaoqiang，SHI Qingyu. Recent advances in numerical simulation of material flow behavior during frictions stir welding[J]. Journal of Mechanical Engineering，2015，51(22)：11-21.
[16] YANG C，CHEN G，QIAO J，et al. Material flow during dissimilar friction stir welding of Al/Mg alloys[J]. International Journal of Mechanical Sciences，2024，272：109173.
[17] YANG C，WU C，SHI L. Modeling the dissimilar material flow and mixing in friction stir welding of aluminum to magnesium alloys[J]. Journal of Alloys and Compounds，2020，843：156021.
[18] ZHAO W，ZHU Y，LIU Z，et al. Mechanism of ultrasonic effects on thermal-stress field in Cu/Al-FSW process[J]. International Journal of Mechanical Sciences，2024，270：109101.
[19] 段亚雄，刘其鹏，高月华，等. 基于CEL方法的Al/Mg搅拌摩擦焊温度场及材料混合流动研究[J]. 稀有金属材料与工程，2023，52(7)：2565-2572. DUAN Yaxiong，LIU Qipeng，GAO Yuehua，et al. Temperature field and material mixing flow in friction stir welding of dissimilar Al/Mg alloys based on CEL approach[J]. Rare Metal Materials and Engineering，2023，52(7)：2565-2572.
[20] MUHAMMAD N A，GENG P，WU C，et al. Unravelling the ultrasonic effect on residual stress and microstructure in dissimilar ultrasonic-assisted friction stir welding of Al/Mg alloys[J]. International Journal of Machine Tools and Manufacture，2023，186：104004.
[21] GENG P，MORIMURA M，WU S，et al. Prediction of residual stresses within dissimilar Al/steel friction stir lap welds using an Eulerian-based modeling approach[J]. Journal of Manufacturing Processes，2022，79：340-355.
[22] LIU X，CHEN G，NI J，et al. Computational fluid dynamics modeling on steady-state friction stir welding of aluminum alloy 6061 to TRIP steel[J]. Journal of Manufacturing Science and Engineering，2017，139(5)：051004.
[23] 于海洋，胡志力. DP590钢/7075铝异种金属搅拌摩擦搭接焊界面组织与力学性能研究[J]. 机械工程学报，2020，56(6)：65-72. YU Haiyang，HU Zhili. Investigation of interfacial microstructure and mechanical properties for DP590 steel/7075 aluminum dissimilar materials friction stir lap welding joints[J]. Journal of Mechanical Engineering，2020，56(6)：65-72.
[24] HEIDARZADEH A，MIRONOV S，KAIBYSHEV R，et al. Friction stir welding/processing of metals and alloys：A comprehensive review on microstructural evolution[J]. Progress in Materials Science，2021，117：100752.
[25] SIMAR A，AVETTAND-FÈNOËL M. State of the art about dissimilar metal friction stir welding[J]. Science and Technology of Welding and Joining，2017，22(5)：389-403.
[26] CHEN Z，SHI L，SU H，et al. Numerical and experimental investigation on intermetallic compounds formation in ultrasonic vibration enhanced friction stir welding of dissimilar Al/Mg alloys[J]. Journal of Alloys and Compounds，2024，977：173426.
[27] TANG J，SHI L，WU C，et al. Development of novel double-side friction stir Z shape butt-lap welding process for dissimilar joining of 12 mm medium-thick Al/Cu plates[J]. Materials Letters，2023，331：133445.
[28] ZHAO J，WU C，SHI L，et al. Evolution of microstructures and intermetallic compounds at bonding interface in friction stir welding of dissimilar Al/Mg alloys with/without ultrasonic assistance[J]. Journal of Materials Science & Technology，2023，139：31-46.
[29] TANAKA T，HIRATA T，SHINOMIYA N，et al. Analysis of material flow in the sheet forming of friction-stir welds on alloys of mild steel and aluminum[J]. Journal of Materials Processing Technology，2015，226：115-124.
[30] ZHANG X，SHI L，WU C，et al. Multi-phase modelling of heat and mass transfer during Ti/Al dissimilar friction stir welding process[J]. Journal of Manufacturing Processes，2023，94：240-254.
[31] SHI L，WU C S，LIU H J. The effect of the welding parameters and tool size on the thermal process and tool torque in reverse dual-rotation friction stir welding[J]. International Journal of Machine Tools and Manufacture，2015，91：1-11.
[32] FONDA R W，BINGERT J F，COLLIGAN K J. Development of grain structure during friction stir welding[J]. Scripta Materialia，2004，51(3)：243-248.
[33] 张鑫，吴鸿燕，陈玉华，等. 中间层Ni对TC4/2A14异种金属搅拌摩擦焊接头组织和性能的影响[J]. 精密成形工程，2023，15(11)：140-146. ZHANG Xin，WU Hongyan，CHEN Yuhua，et al. Effect of Ni interlayer on microstructure and properties of TC4/2A14 dissimilar metal joints welded by friction stir welding[J]. Journal of Netshape Forming Engineering，2023，15(11)：140-146.
[34] KAR A，KAILAS S V，SUWAS S. Formation sequence of intermetallics and kinetics of reaction layer growth during solid state reaction between titanium and aluminum[J]. Materialia，2020，11：100702.
[35] THIYANESHWARAN N，SIVAPRASAD K，RAVISANKAR B. Characterization based analysis on TiAl3 intermetallic phase layer growth phenomenon and kinetics in diffusion bonded Ti/TiAl3/Al laminates[J]. Materials Characterization，2021，174：110981.
[36] TARDY J，TU K N. Solute effect of Cu on interdiffusion in Al₃Ti compound films[J]. Physical Review B，1985，32(4)：2070-2081.
[37] FU X，CHEN K，ZHANG Q，et al. Interfacial intermetallic compound layer in friction stir welded Mg/Al joints：Relationship between thickness and the welding temperature history[J]. Journal of Magnesium and Alloys，2023:257268039.
[38] ZHANG X，WANG X，LI Y，et al. Eliminating root defect in Al/Ti dissimilar friction stir welded via the double-side process[J]. Science and Technology of Welding and Joining，2023，28(8)：803-809.