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M Mehta, K Chatterjee & A De. (2013) Monitoring torque and traverse force in friction stir welding from input electrical signatures of driving motors. Science and Technology of Welding and Joining 18:3, pages 191-197.
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A P Gerlich & T Shibayanagi. (2011) Liquid film formation and cracking during friction stir welding. Science and Technology of Welding and Joining 16:4, pages 295-299.
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R M Leal, N Sakharova, P Vilaça, D M Rodrigues & A Loureiro. (2011) Effect of shoulder cavity and welding parameters on friction stir welding of thin copper sheets. Science and Technology of Welding and Joining 16:2, pages 146-152.
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J. D. Robson & L. Campbell. (2010) Model for grain evolution during friction stir welding of aluminium alloys. Science and Technology of Welding and Joining 15:2, pages 171-176.
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M.M. Shtrikman. (2008) Current state and development of friction stir welding Part 3. Industrial application of friction stir welding. Welding International 22:11, pages 806-815.
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L. Fratini, G. Buffa, D. Palmeri, J. Hua & R. Shivpuri. (2006) Material flow in FSW of AA7075–T6 butt joints: numerical simulations and experimental verifications. Science and Technology of Welding and Joining 11:4, pages 412-421.
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H. X. Wang, C. L. Yang, Y. H. Wei, S. B. Lin & H. Y. Shen. (2006) Study of keyhole closure and analysis of microstructure and mechanical performance of weld joints for variable polarity vertical up plasma arc welding process. Science and Technology of Welding and Joining 11:3, pages 315-325.
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Articles from other publishers (68)
Guido Di Bella, Federica Favaloro & Chiara Borsellino. (2023) Effect of Process Parameters on Friction Stir Welded Joints between Dissimilar Aluminum Alloys: A Review. Metals 13:7, pages 1176.
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Sanjeev Kumar, Jitendra Kumar Katiyar, Guru Sewak Kesharwani & Barnik Saha Roy. (2023) Microstructure, mechanical, and force-torque generation properties of friction stir welded third generation Al/Li alloy at higher traverse speed. Materials Today Communications 35, pages 106084.
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Lei Shi, Jie Chen, Chunliang Yang, Gaoqiang Chen & Chuansong Wu. (2023) Thermal-fluid-structure coupling analysis of void defect in friction stir welding. International Journal of Mechanical Sciences 241, pages 107969.
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Kevin Colligan. 2023. Friction Stir Welding and Processing XII. Friction Stir Welding and Processing XII
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Yanyan Feng, Fan Yang & Yan Bi. (2022) Effect of Friction Stir Weld Parameters on Mechanical and Corrosion Performances of 5A06 Aluminum Alloy Plate Joints in 3.5 wt% NaCl solution. International Journal of Electrochemical Science 17:10, pages 221039.
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J.Y. Li, Z. Zhang, D.X. Ren, W. Zhang & Z.J. Tan. (2022) The experimental and numerical studies on load bearing capacity in lamellar tearing of friction stir lap weld. Engineering Fracture Mechanics 271, pages 108609.
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Mouminah Amatullah, Mehwish Jan, Munazah Farooq, Afra Saeed Zargar, Annayath Maqbool & Noor Zaman Khan. (2022) Effect of tool rotational speed on the friction stir welded aluminum alloys: A review. Materials Today: Proceedings 62, pages 245-250.
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Karen J. Quintana & Jose Luis L. Silveira. (2021) Threaded pin effects analysis on forces in FSW. Journal of the Brazilian Society of Mechanical Sciences and Engineering 43:11.
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Neves Manuel, Daniel Beltrão, Ivan Galvão, Rui M. Leal, José D. Costa & Altino Loureiro. (2021) Influence of Tool Geometry and Process Parameters on Torque, Temperature, and Quality of Friction Stir Welds in Dissimilar Al Alloys. Materials 14:20, pages 6020.
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Yi-Jie Hu, You-Ping Sun, Shi-Peng Zhou, Jiang-Mei He & Chun-Yang Yang. (2021) Effect of a cooling method on the structural and mechanical properties of friction stir spot welding with a 2524 aluminum alloy. Materials Research Express 8:2, pages 026517.
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Nasir Khan, Sandeep Rathee & Manu Srivastava. (2021) Friction stir welding: An overview on effect of tool variables. Materials Today: Proceedings 47, pages 7196-7202.
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Maneesh Tewari, R.S. Jadoun & Sandeep Kumar. (2021) Effect of process parameters on tensile strength of Friction stir welded butt joints of thick AA1350 aluminum plates using Taguchi experimental design. Materials Today: Proceedings 44, pages 2721-2725.
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Shubhashree Mohapatra & Hrushikesh Sarangi. (2021) Experimental investigation of tool probe shape and rotational speed on weld quality of friction stir welding of aluminium alloy. Materials Today: Proceedings 41, pages 422-425.
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François Nadeau, Benoit Thériault & Marc-Olivier Gagné. (2020) Machine learning models applied to friction stir welding defect index using multiple joint configurations and alloys. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications 234:5, pages 752-765.
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Umasankar Das, Ratnakar Das & Vijay Toppo. (2020) Dry sliding wear behavior study on friction stir weld joints of dissimilar aluminum alloys. Materials Today: Proceedings 26, pages 1815-1821.
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Yasuko Besel, Michael Besel, Eric Dietrich, Janine Wischek, Ulises Alfaro Mercado, Toshifumi Kakiuchi & Yoshihiko Uematsu. (2019) Heterogeneous local straining behavior under monotonic and cyclic loadings in a friction stir welded aluminum alloy. International Journal of Fatigue 125, pages 138-148.
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D. Balaji Naik, C.H. Venkata Rao, K. Srinivasa Rao, G. Madhusudan Reddy & G. Rambabu. (2019) Optimization of Friction Stir Welding Parameters to Improve Corrosion Resistance and Hardness of AA2219 Aluminum Alloy Welds. Materials Today: Proceedings 15, pages 76-83.
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Nikolai Kashaev, Volker Ventzke & Gürel Çam. (2018) Prospects of laser beam welding and friction stir welding processes for aluminum airframe structural applications. Journal of Manufacturing Processes 36, pages 571-600.
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Zijiang Yang, Yuksel C. Yabansu, Reda Al-Bahrani, Wei-keng Liao, Alok N. Choudhary, Surya R. Kalidindi & Ankit Agrawal. (2018) Deep learning approaches for mining structure-property linkages in high contrast composites from simulation datasets. Computational Materials Science 151, pages 278-287.
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Morteza Ansaripour, Abdol Reza Soltanipour & Mohamad Reza Dehnavi. (2018) Microstructural features and corrosion analysis of A517 steel joint processed by friction stir welding. Materials Research Express 5:6, pages 066543.
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