Fabrication of welded hybrid joints of aluminum alloys and polymer composites with significantly enhanced long-term reliability

Chunyang Jiang; Fengchao Liu; Lihui Wu; Ying Kan; Xianjun Pei; Hao Zhang; Zhen Zhang; Peng Xue; Dingrui Ni; Bolv Xiao; Zongyi Ma

doi:10.1007/s12613-025-3244-1

International Journal of Minerals, Metallurgy, and Materials ›› 2025, Vol. 32 ›› Issue (12) :3029 -3042. DOI: 10.1007/s12613-025-3244-1

Research Article

research-article

Fabrication of welded hybrid joints of aluminum alloys and polymer composites with significantly enhanced long-term reliability

Chunyang Jiang ¹^,²
, Fengchao Liu ¹^,²^,^a
, Lihui Wu ¹^,³^,^b
, Ying Kan ¹^,²
, Xianjun Pei ⁴
, Hao Zhang ¹^,²
, Zhen Zhang ¹^,²
, Peng Xue ¹^,³
, Dingrui Ni ¹
, Bolv Xiao ¹^,³
, Zongyi Ma ¹^,²

Author information +

History +

PDF

Abstract

The effect of thermal degradation on the welded hybrid joints of metal and polymer composites is insufficient, which seriously inhibits the engineering applications of the joints. In this study, robust hybrid joints of metal and polymer composites were fabricated by the combination of friction lap welding (FLW) and laser surface treatment for investigating the effect of accelerated aging on the joint properties. Results showed that the FLW hybrid joints without laser surface treatment exhibited 91% reduction in the tensile shear force (TSF) after 7 days of accelerated aging tests. In contrast, the FLW hybrid joints with suitable laser surface treatment exhibited only 26% reduction in TSF even after 35 days of accelerated aging tests. Fractures of the tensile specimens occurred across the composite plates rather than along the joint interface. The enhanced reliability of the hybrid joints was mainly attributed to (1) the formation of micromechanical interlocking between the polymer composites and aluminum alloy plate, and (2) the modification of the stress distribution along the joint interface.

Keywords

Cite this article

Download citation ▾

Chunyang Jiang, Fengchao Liu, Lihui Wu, Ying Kan, Xianjun Pei, Hao Zhang, Zhen Zhang, Peng Xue, Dingrui Ni, Bolv Xiao, Zongyi Ma. Fabrication of welded hybrid joints of aluminum alloys and polymer composites with significantly enhanced long-term reliability. International Journal of Minerals, Metallurgy, and Materials, 2025, 32(12): 3029-3042 DOI:10.1007/s12613-025-3244-1

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Xie YJ, Hill CAS, Xiao ZF, Militz H, Mai C. Silane coupling agents used for natural fiber/polymer composites: A review. Composites, Part A. 2010, 41(7): 806

[2]	Han SL, Guang XJ, Li ZY, Li Y. Joining processes of CFRP–Al sheets in automobile lightweighting technologies: A review. Polym. Compos.. 2022, 43(12): 8622

[3]	Feistauer EE, dos Santos JF, Amancio-Filho ST. A review on direct assembly of through-the-thickness reinforced metal–polymer composite hybrid structures. Polym. Eng. Sci.. 2019, 59(4): 661

[4]	G. Zheng, Z.K. He, K. Wang, et al., On failure mechanisms in CFRP/Al adhesive joints after hygrothermal aging degradation following by mechanical tests, Thin Walled Struct., 158(2021), art. No. 107184.

[5]	Lambiase F. Mechanical behaviour of polymer–metal hybrid joints produced by clinching using different tools. Mater. Des.. 2015, 87: 606

[6]	Liu FC, Liao J, Nakata K. Joining of metal to plastic using friction lap welding. Mater. Des.. 2014, 54: 236

[7]	Y.C. Liu, X.B. Wang, L. Zhou, et al., Achievement of high-strength Al/CFRP hybrid joint via high-speed friction stir lap joining and laser texturing pretreatment parameters variation, Thin Walled Struct., 199(2024), art. No. 111762.

[8]	X.Y. Bi, H. Liu, Y. Li, M.J. Xu, and Z.M. Wang, Biomimetic papilla texture by femtosecond laser for high-strength CFRTP/A6061-T6 FSSW hybrid structures, Composites, Part B, 281(2024), art. No. 111500.

[9]	Jiang CY, Wu LH, Liu FC, et al. . Bonding mechanisms of carbon fiber-reinforced plastic/aluminum alloy interface during friction lap welding via silane coupling treatment. J. Mater. Res. Technol.. 2024, 29: 3340

[10]	F.C. Liu, P. Dong, and X. Pei, A high-speed metal-to-polymer direct joining technique and underlying bonding mechanisms, J. Mater. Process. Technol., 280(2020), art. No. 116610.

[11]	F.C. Liu, A.H. Feng, X. Pei, Y. Hovanski, R.S. Mishra, and Z.Y. Ma, Friction stir based welding, processing, extrusion and additive manufacturing, Prog. Mater. Sci., 146(2024), art. No. 101330.

[12]	Shen YJ, Wang JJ, Wang BB, et al. . Strengthening strategy for high-performance friction stir lap welded joints based on 5083 Al alloy. Int. J. Miner. Metall. Mater.. 2024, 31(11): 2498

[13]	Xie GM, Duan RH, Wang YQ, Luo ZA, Wang GD. Microstructure and toughness of thick-gauge pipeline steel joint via double-sided friction stir welding combined with preheating. Int. J. Miner. Metall. Mater.. 2023, 30(4): 724

[14]	Wang ZW, Zhang M, Li C, et al. . Achieving a high-strength dissimilar joint of T91 heat-resistant steel to 316L stainless steel via friction stir welding. Int. J. Miner. Metall. Mater.. 2023, 30(1): 166

[15]	Z.W. Feng, X.Y. Zhang, C.L. Qin, et al., Improvement of interfacial thermal contact conductance and mechanical performance of metal-composite joint via controlling anchoring structures, Thin Walled Struct., 200(2024), art. No. 111882.

[16]	Staab F, Balle F. Ultrasonic torsion welding of ageing-resistant Al/CFRP joints: Properties, microstructure and joint formation. Ultrasonics. 2019, 93: 139

[17]	X.Y. Zhang, J.H. Su, Z.W. Feng, et al., Effect of laser textured patterns on the interfacial characteristics and mechanical properties of 6061Al/GFRTP joints via hot-pressing, Thin Walled Struct., 189(2023), art. No. 110916.

[18]	Xie Y, Zhang JH, Zhou T. Large-area mechanical interlocking via nanopores: Ultra-high-strength direct bonding of polymer and metal materials. Appl. Surf. Sci.. 2019, 492: 558

[19]	P. Kustron, M. Korzeniowski, T. Piwowarczyk, and P. Sokolowski, Development of resistance spot welding processes of metal-plastic composites, Materials, 14(2021), No. 12, art. No. 3233.

[20]	F. Lambiase, S.I. Scipioni, C.J. Lee, D.C. Ko, and F.C. Liu, A state-of-the-art review on advanced joining processes for metal-composite and metal–polymer hybrid structures, Materials, 14(2021), No. 8, art. No. 1890.

[21]	Liu FC, Dong PS. Directly and reliably welding plastic to metal. Welding J.. 2022, 101(5): 45

[22]	Liu FC, Liao J, Gao Y, Nakata K. Effect of plasma electrolytic oxidation coating on joining metal to plastic. Sci. Technol. Weld. Joining. 2015, 20(4): 291

[23]	Wu LH, Nagatsuka K, Nakata K. Achieving superior mechanical properties in friction lap joints of copper to carbon-fiber-reinforced plastic by tool offsetting. J. Mater. Sci. Technol.. 2018, 34(9): 1628

[24]	Liu FC, Nakata K, Liao J, Hirota S, Fukui H. Reducing bubbles in friction lap welded joint of magnesium alloy and polyamide. Sci. Technol. Weld. Joining. 2014, 19(7): 578

[25]	Nagatsuka K, Kitagawa D, Yamaoka H, Nakata K. Friction lap joining of thermoplastic materials to carbon steel. ISIJ Int.. 2016, 56(7): 1226

[26]	L.X. Li, J.N. Chuan, S. Xu, et al., Enhanced joint strength between TC4 alloy and CFRTP via in situ constructing sandwich interface with interlocking structure and multi-chemical bonding, Compos. Struct., 310(2023), art. No. 116769.

[27]	L.H. Wu, B.L. Xiao, K. Nagatsuka, K. Nakata, and Z.Y. Ma, Achieving strong friction lap joints of carbon-fiber reinforced plastic and metals by modifying metal surface structure via laser-processing pretreatment, Compos. Struct., 242(2020), art. No. 112167.

[28]	Han SC, Wu LH, Jiang CY, et al. . Achieving a strong polypropylene/aluminum alloy friction spot joint via a surface laser processing pretreatment. J. Mater. Sci. Technol.. 2020, 50: 103

[29]	C.Y. Jiang, L.H. Wu, F.C. Liu, et al., Achieving a strong friction-lap joint of continuous carbon-fiber-reinforced plastic/aluminum alloy via a surface laser-processing pretreatment, Adv. Eng. Mater., 25(2023), No. 19, art. No. 2370063.

[30]	Huang ZQ, Sugiyama S, Yanagimoto J. Hybrid joining process for carbon fiber reinforced thermosetting plastic and metallic thin sheets by chemical bonding and plastic deformation. J. Mater. Process. Technol.. 2013, 213(11): 1864

[31]	Okada T, Uchida S, Nakata K. Direct joining of aluminum alloy and plastic sheets by friction lap processing. Mater. Sci. Forum. 2014, 794–796: 395

[32]	Lambiase F, Paoletti A, Grossi V, Genna S. Improving energy efficiency in friction assisted joining of metals and polymers. J. Mater. Process. Technol.. 2017, 250: 379

[33]	Y. Wei, X.H. Jin, Q.T. Luo, Q. Li, and G.Y. Sun, Adhesively bonded joints–A review on design, manufacturing, experiments, modeling and challenges, Composites, Part B, 276(2024), art. No. 111225.

[34]	Y. Su, M.R. Zhou, W.Y. Li, et al., Microstructural evolution and mechanical behavior of TA5 titanium alloy joint in low-temperature friction stir welding with various cooling rates, Eng. Fail. Anal., 176(2025), art. No. 109667.

[35]	Yang XW, Meng TX, Chu Q, et al. . A review of linear friction welding of Ni-based superalloys. Int. J. Miner. Metall. Mater.. 2024, 31(6): 1382

[36]	Yang JH, Wu LY, Lian Y, et al. . Texture, residual stress and mechanical properties of 7039-T6 thick plate Al alloy with MIG-welded laminar tearing. Int. J. Miner. Metall. Mater.. 2025, 32(5): 1176

[37]	Luo ZA, Zhang X, Liu ZS, Zhou HY, Wang MK, Xie GM. Mechanical properties and interfacial characteristics of 6061 Al alloy plates fabricated by hot-roll bonding. Int. J. Miner. Metall. Mater.. 2024, 31(8): 1890

[38]	Liu HB, Hou R, Wu CH, Xie RS, Chen SJ. Multi-layer multi-pass friction rolling additive manufacturing of Al alloy: Toward complex large-scale high-performance components. Int. J. Miner. Metall. Mater.. 2025, 32(2): 425

[39]	Yin S, Cavaliere P, Aldwell B, et al. . Cold spray additive manufacturing and repair: Fundamentals and applications. Addit. Manuf.. 2018, 21: 628

[40]	W.L. Mu, S.J. Li, X.L. Chen, et al., Effect of service temperature and hygrothermal aging coupling on mechanical properties of adhesively bonded BFRP-aluminum alloy joints, Int. J. Adhes. Adhes., 130(2024), art. No. 103637.

[41]	Y. Li, X.W. Ma, H.Y. Li, et al., Effect of moisture-heat coupling on mechanical behavior of nano-SiO₂ adhesives and CFRP-steel lap joints, Thin Walled Struct., 183(2023), art. No. 110391.

[42]	J. He, G.J. Xian, and Y.X. Zhang, Effect of moderately elevated temperatures on bond behaviour of CFRP-to-steel bonded joints using different adhesives, Constr. Build. Mater., 241(2020), art. No. 118057.

[43]	Na JX, Mu WL, Qin GF, Tan W, Pu LX. Effect of temperature on the mechanical properties of adhesively bonded basalt FRP-aluminum alloy joints in the automotive industry. Int. J. Adhes. Adhes.. 2018, 85: 138

[44]	Yao MX, Zhu DJ, Yao YM, Zhang HA, Mobasher B. Experimental study on basalt FRP/steel single-lap joints under different loading rates and temperatures. Compos. Struct.. 2016, 145: 68

[45]	Nguyen TC, Bai Y, Zhao XL, Al-Mahaidi R. Mechanical characterization of steel/CFRP double strap joints at elevated temperatures. Compos. Struct.. 2011, 93(6): 1604

[46]	Geng PH, Ma NS, Ma H, et al. . Flat friction spot joining of aluminum alloy to carbon fiber reinforced polymer sheets: Experiment and simulation. J. Mater. Sci. Technol.. 2022, 107: 266

[47]	Na JX, Gao Y, Mu WL, Shen H, Qin GF, Tan W. Effect of high temperature exposure on adhesively bonded basalt fiber reinforced polymer composite-aluminum alloy single lap joints. Acta Mater. Compos. Sin.. 2020, 37(1): 140

[48]	E. Zavvar, F. Sousa, F. Taveira-Pinto, and P. Rosa Santos, Multivariate data analysis of maximum stress concentration factors in FRP-retrofitted two-planar KT-joints under axial loads for offshore renewables, J. Mar. Sci. Eng., 12(2024), No. 8, art. No. 1451.

[49]	Chung TF, Yang YL, Hsiao CN, et al. . Morphological evolution of GP zones and nanometer-sized precipitates in the AA2050 aluminium alloy. Int. J. Lightweight Mater. Manuf.. 2018, 1(3): 142

[50]	X.L. Zhou, Z.Y. Liu, F.C. Liu, B.L. Xiao, and Z.Y. Ma, High-proportion intragranular nano-Al₂O₃ induced high strength-ductility Al matrix nano-composites via additive friction extrusion deposition, Compos. Commun., 55(2025), art. No. 102332.

[51]	S.Y. Wang, W.Q. Wang, Y.X. Xu, Y.T. Tian, X.G. Zhang, and H. Huang, Enhancing bonding synergy and mechanical response of metal/composite hybrid joints through physicochemical surface pretreatment, J. Mater. Process. Technol., 315(2023), art. No. 117923.

[52]	Yu P, Deng CJ, Ma NG, Yau MY, Ng DHL. Formation of nanostructured eutectic network in a-Al₂O₃ reinforced Al–Cu alloy matrix composite. Acta Mater.. 2003, 51(12): 3445

[53]	Liu FC, Dong P, Lu W, Sun K. On formation of Al–O–C bonds at aluminum/polyamide joint interface. Appl. Surf. Sci.. 2019, 466: 202

[54]	X.Y. Bi, Z.M. Wang, M.J. Xu, and X.P. Li, Femtosecond laser fabricated micro/nano interfacial structures to strengthen CFRPEEK/A6061-T6 FLJ hybrid joints, Composites, Part B, 231(2022), art. No. 109540.

[55]	W.L. Mu, Q.H. Xu, J.X. Na, Y.S. Fan, Y.F. Sun, and Y. Liu, Investigating the failure behavior of hygrothermally aged adhesively bonded CFRP-aluminum alloy joints using modified Ar-can fixture, Thin Walled Struct., 182(2023), art. No. 110303.

[56]	Y. Bai, T.C. Nguyen, X.L. Zhao, and R. Al-Mahaidi, Environment-assisted degradation of the bond between steel and carbon-fiber-reinforced polymer, J. Mater. Civ. Eng., 26(2014), No. 9, art. No. 04014054.

[57]	Wang X, Hu Y, Song L, Xing WY, Lu HD. Thermal degradation mechanism of flame retarded epoxy resins with a DOPO-substitued organophosphorus oligomer by TG-FTIR and DP-MS. J. Anal. Appl. Pyrolysis. 2011, 92(1): 164

[58]	Y. Shin, Y. Qiao, Y.L. Ni, et al., Interfacial bond characterization of epoxy adhesives to aluminum alloy and carbon fiber-reinforced polyamide by vibrational spectroscopy, Surf. Interfaces, 42(2023), art. No. 103346.