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Abstract

This research focused on the characteristics of the AA6061/AA5083 alloy joints which are fabricated by the friction stir welding (FSW) technique. The impact of FSW parameters such as tool tilt angle, pin depth, and tool geometry on the mechanical properties and fractographic characteristics were studied. Ultimate tensile strength (UTS), hardness (HBN), and specific wear rate (SWR) were examined for characterization while fractography analyses were done using scanning electron microscopy. Taguchi-Grey relational analysis (GRA) was employed to execute multicriteria optimization and recognize the best grouping of parameters. The optimized values attained from this analysis were 259.2 MPa for UTS, 94.9 HV for HBN, and 0.0819 m³/Nm for SWR. The analysis of variance (ANOVA) results derived from the GRA revealed that tool geometry exerted the most significant influence (39.79%) on output factors, followed by pin depth (24.90%) and tilt angle (24.26%). To enhance the predictive accuracy of the output responses, an artificial neural network (ANN) model was developed utilizing the Levenberg-Marquardt (LM) algorithm. The optimized ANN architecture, configured as (3–10–3), exhibited robust regression analysis outcomes, showcasing correlation coefficients (R) of 0.99999, 0.99967, and 0.99994 for the training, validation, and test datasets. The overall R-value, computed at 0.99958, affirmed high conformity between experimental and predicted values.

Keywords

Friction stir welding tensile strength specific wear rate scanning electron microscope grey relational analysis regression analysis

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References

Sundararaj

Naga Swapna Sri

Peyyala

, et al. Grey-Taguchi approach for optimizing FSW parameters in joining AA6262 and AA5083 alloys. Chiang Mai J Sci 2024; 51: 1–16.

Thomas

Nicholas

Needham

, et al. International Patent Application No. PCT/GB92/02203 and GB Patent 460 (1991) 317.

Shaik

Pawale

Suryanarayanan

, et al. Improving the mechanical properties of 6061 and 5083 welded joint using friction stir lap welding. J Phys Conf Ser 2021; 1969: 012017.

Verma

Kumar

. Optimization of friction stir welding parameters of dissimilar aluminium alloys 6061 and 5083 by using response surface methodology. Proc Inst Mech Eng Part C 2021; 235: 7009–7020.

Yadav

Trivedi

Varma

, et al. Examination of mechanical property for friction stir welding joint of Al6061 and Al5083. Mater Today Proc 2020; 24: 731–737.

Casalino

Campanelli

Mortello

. Influence of shoulder geometry and coating of the tool on the friction stir welding of aluminium alloy plates. Procedia Eng 2014; 69: 1541–1548.

Shanmuga Sundaram

Murugan

. Tensile behavior of dissimilar friction stir welded joints of aluminium alloys. Mater Des 2010; 31: 4184–4193.

Ghaffarpour

Kazemi

Mohammadi Sefat

, et al. Evaluation of dissimilar joints properties of 5083-H12 and 6061-T6 aluminum alloys produced by tungsten inert gas and friction stir welding. Proc Inst Mech Eng L 2017; 231: 297–308.

Rajakumar

Muralidharan

Balasubramanian

. Predicting tensile strength, hardness and corrosion rate of friction stir welded AA6061-T6 aluminium alloy joints. Mater Des 2011; 32: 2878–2890.

10.

Suryanarayanan

Sridhar

. Effect of process parameters in pinless friction stir spot welding of Al 5754-Al 6061 alloys. Metallogr Microstruct Anal 2020; 9: 261–272.

11.

AbuShanab

Abd Elaziz

Ghandourah

, et al. A new fine-tuned random vector functional link model using hunger games search optimizer for modeling friction stir welding process of polymeric materials. J Mater Res Technol 2021; 14: 1482–1493.

12.

Aydin

Bayram

Esme

, et al.

Application of grey relation analysis (GRA) and Taguchi method for the parametric optimization of friction stir welding (FSW) process.

Mater Technol 2010; 44: 205–211.

13.

Vijayan

Raju

Rao

SRK

. Multiobjective optimization of friction stir welding process parameters on aluminum alloy AA5083 using Taguchi-based grey relation analysis. Mater Manuf Processes 2010; 25: 1206–1212.

14.

Wable

Patil

Pardeshi

. Artificial neural network prediction and grey relational grade optimisation of friction stir processing. Cogent Eng 2023; 10(1): 2107760.

15.

Shunmugasundaram

Praveen Kumar

Ponraj Sankar

, et al. Optimization of process parameters of friction stir welded dissimilar AA6063 and AA5052 aluminum alloys by Taguchi technique. Mater Today Proc 2020; 27: 871–876.

16.

Kumar

Rana

Purohit

, et al. Optimization of dry sliding wear behavior of Si₃N₄ and Gr reinforced Al–Zn–Mg–Cu composites using Taguchi method. J Mater Res Technol 2022; 19: 4793–4803.

17.

Rajaseelan

Kumarasamy

. Mechanical properties and microstructural characterization of dissimilar friction stir welded AA5083 and AA6061 aluminium alloys. Mechanics 2020; 26: 545–552.

18.

Ahmed

MMZ

El-Sayed Seleman

Fydrych

, et al. Friction stir welding of aluminum in the aerospace industry: the current progress and state-of-the-art review. Materials (Basel) 2023; 16: 2971.

19.

Veličković

Stojanović

Babić

, et al. Optimization of tribological properties of aluminum hybrid composites using Taguchi design. J Compos Mater 2017; 51: 2505–2515.

20.

Soorya Prakash

Gopal

Karthik

. Multi-objective optimization using Taguchi based grey relational analysis in turning of Rock dust reinforced Aluminum MMC. Measurement 2020; 157: 107664.

21.

Stephens

. EDF statistics for goodness of fit and some comparisons. J Am Stat Assoc 1974; 69: 730–737.

22.

Qazi

Akhtar

Abas

, et al. An integrated approach of GRA coupled with principal component analysis for multi-optimization of shielded metal arc welding (SMAW) process. Materials (Basel) 2020; 13: 3457.

23.

Elmolla

Chaudhuri

Eltoukhy

. The use of artificial neural network (ANN) for modeling of COD removal from antibiotic aqueous solution by the Fenton process. J Hazard Mater 2010; 179: 127–134.

24.

Rufina R

Uthayakumar

Thangavelu

. Prediction of the size of green synthesized silver nanoparticles using RSM-ANN-LM hybrid modeling approach. Chem Phys Impact 2023; 6: 100231.

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ANN modeling and optimization of friction stir welding performance for AA6061 and AA5083 alloy joints

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