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Abstract

The final quality of the consecutive resistance spot weld (RSW) joints depends on the parameters including the welding time, welding distance, etc. Welding interval defined as the off time between the welding process of the two adjacent weld spots influences the quality of the next joint due to the contributions of the heating and pre-heating processes caused by the current local temperature distribution of the sheet and electrodes. In this paper, the influence of the timing interval between the two weld spots has been analyzed on the AA-2219 RSW joints, while the metallurgical and mechanical behavior of the final joint are analyzed experimentally and numerically. Temperature history and distribution of the final spot has been obtained using the finite-element analysis results, while microstructure and tensile-shear strength of the final spot weld have been evaluated experimentally. Timing interval has been set as the main variable for two consecutive nuggets with 5 mm welding distance, with the value of 0.5, 1, and 1.5 s. The results demonstrated that the longer interval has led to slightly faster cooling rates, less tensile-shear strength (0.6%), more asymmetric HAZ spread (15%) due to shunting intensification, and slightly smaller nuggets (about 2.5%), while the shorter interval had the reverse effects together with minor pre-heating.

Keywords

Shunting effect metallurgical aspects numerical analysis timing intervals

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References

Hard

. Preliminary test of spot weld shunting in 24ST Alclad. Weld J 1948; 27: 491–495.

Chang

Cho

. A study on the shunt effect in resistance spot welding. Weld J 1990; 69: 308–316.

Senkara

Zhang

. Cracking in spot welding aluminum alloy AA5754. Weld J-New York 2000; 79: 194-s.

Zhang

Senkara

. Suppressing cracking in resistance welding AA5754 by mechanical means. J Manuf Sci Eng 2002; 124: 79–85.

Wang

Lou

Shen

, et al. Shunting effect in resistance spot welding steels—part 1: experimental study. Weld J 2013; 92: 182s–189s.

Xing

Xiao

Qin

. Characteristics of shunting effect in resistance spot welding in mild steel based on electrode displacement. Measurement 2018; 115: 233–242.

Jafari Vardanjani

Araee

Senkara

, et al. Metallurgical effects of shunting current on resistance spot-welded joints of AA2219 sheets. J Mater Eng Perform 2016; 25: 3506–3517. doi:https://doi.org/10.1007/s11665-016-2168-3.

Jafari Vardanjani

Araee

Senkara

, et al. Theoretical analysis of shunting effect in resistance spot welding (RSW) of AA2219. J Chin Inst Eng 2016; 39: 907–918.

Jafari Vardanjani

Senkara

. Effect of multi-pulsed current mechanism on shunting current in resistance spot welding (RSW) of AA-2219 sheets. Exp Tech 2021; 66: 661–675.

10.

Vardanjani

Senkara

. A theoretical analysis of vibrational stress relief in AISI 1008 as a mechanical treatment. Arch Mech Eng 2021; 64: 353–374.

11.

Vardanjani

Araee

Senkara

, et al. Experimental and numerical analysis of shunting effect in resistance spot welding of Al2219 sheets. Bull Pol Acad Sci Techn Sci 2016; 64: 425–434.

12.

Vardanjani

Araee

Senkara

, et al. Influence of shunting current on the metallurgical and mechanical behaviour of resistance spot-welded joints in AA2219 joints. Strojniski Vestnik - J Mech Eng 2016; 62: 625–635. shunting effect; heat affected zone; tensile-shear strength; failure type; finite element method 2016-10-25..

13.

Bamberg

Gintrowski

Liang

, et al. Development of a new approach to resistance spot weld AW-7075 aluminum alloys for structural applications: an experimental study – part 1. J Mater Res Technol 2021; 15: 5569–5581.

14.

T-L

Rao

Y-Z

Zhang

Q-X

, et al. Effect of storage time on the surface status and resistance spot weldability of TiZr pretreated 5182 aluminum alloy. J Manuf Process 2022; 81: 166–176.

15.

Yang

, et al. Microstructure and mechanical properties of 2195/5A06 dissimilar joints made by resistance spot welding. Mater Charact 2022; 191: 112147.

16.

Raj

Biswas

. Effect of induction preheating on microstructure and mechanical properties of friction stir welded dissimilar material joints of Inconel 718 and SS316L. CIRP J Manuf Sci Technol 2023; 41: 160–179.

17.

Wang

Shen

, et al. Shunting effect in resistance spot welding steels—part 2: theoretical analysis. Weld J 2013; 92: 231s–238s.

18.

Shen

Zhang

Lai

, et al. Modeling of resistance spot welding of multiple stacks of steel sheets. Mater Des 2011; 32: 550–560.

19.

Nied

. The finite element modeling of the resistance spot welding process. Weld J 1984; 63: 123.

20.

Zhang

. Design and implementation of software for resistance welding process simulations. SAE Trans 2003; 112: 556–564.

21.

Hamedi

Eisazadeh

Esmailzadeh

. Numerical simulation of tensile strength of upset welded joints with experimental verification. Mater Design (1980–2015) 2010; 31: 2296–2304.

22.

Sun

Dong

. Analysis of aluminum resistance spot welding processes using coupled finite element procedures. Weld J-New York 2000; 79: 215-S.

23.

Zhang

Senkara

. Resistance Welding: Fundamentals and Applications, Second Edition. Boca Raton: CRC Press, 2011.

24.

Ghafelehbashi

Talaee

. Experimental and numerical investigation of thermal-hydraulic performance of bi-metallic (Al-Cu) plate fin heat sink. Proc IMechE, Part E: J Process Mechanical Engineering 2024; 238: 1756–1764.

25.

Kasirajan

Selva Kumar

Ramkumar

, et al. Thermal and mechanical characterisation of friction stir welded dissimilar aluminium alloys. Proc IMechE, Part E: J Process Mechanical Engineering 2024; 238: 09544089241241447. doi:https://doi.org/10.1177/09544089241241447

26.

Wang

Guo

, et al. Effect of modification and subsequent heat treatment on thermal and mechanical properties of near-eutectic Al-Si-Fe-Mg alloys. Proc IMechE, Part E: J Process Mechanical Engineering 2023; 237: 09544089231215226. doi:https://doi.org/10.1177/09544089231215226

27.

Liu

Wei

. Direct finite element analysis of the stress evolution and interaction in resistance spot welding with multiple processes and multiple spots based on reverse engineering technology. J Mater Eng Perform 2020; 29: 5490–5502.

28.

Sessler

Weiss

. Materials data handbook- aluminum alloy 2219. United States: Western Applied Research & Development, 1966.

29.

Committee

AIH

. ASM Handbook: Properties and selection : nonferrous alloys and special-purpose materials. United States: ASM International, 1990.

30.

Vardanjani

Ghayour

Homami

. Analysis of the vibrational stress relief for reducing the residual stresses caused by machining. Exp Tech 2016; 40: 705–713.

31.

Vogler

Sheppard

. Electrical contact resistance under high loads and elevated temperatures. Weld J 1993; 72: 231–238.

32.

Society

Weisman

Kearns

. Welding Handbook: Metals and their weldability. United States: American Welding Society, 1976.

33.

Welding ACoR, Society AW, Committee AWSTA, et al. AWS C1. 1M/C1. 1-2000, Recommended Practices for Resistance Welding. United States: American Welding Society, 2000.

34.

Jafari Vardanjani

Araee

. Analysis of vibratory stress relief (VSR) parameters on mechanical and metallurgical properties of AISI 1008. Period Polytech Mech Eng 2024; 68: 149–161.

35.

Zhang

Senkara

. Resistance Welding: Fundamentals and Applications. Boca Raton: Taylor & Francis, 2005.

36.

Jafari Vardanjani

Senkara

Effect of multi-pulsed current mechanism on shunting current in resistance spot welding (RSW) of AA-2219 sheets. Exp Tech 2022; 46: 661–675. doi:https://doi.org/10.1007/s40799-021-00504-x.

37.

Lumley

. Heat treatment of aluminum alloys. In: Hetnarski

(eds) Encyclopedia of thermal stresses. Dordrecht: Springer Netherlands, 2014, pp.2190–2203.

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Effect of the time intervals on the mechanical and metallurgical quality of AA-2219 resistance spot weld joints

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