Microstructural and Mechanical Characteristics of Pure-Cu/brass Dissimilar Joints Welded by Friction Stir Welding Using Various Process Parameters

FSW (friction stir welding) is a solid-state joining method that attracts interest from all industries. The influence of various tool rotational speeds on the microstructure and mechanical characteristics of dissimilar pure Cu-brass joints has been investigated. The travel speed and vertical load were kept constant in the welding trials, at 40 mm/min and 10 kN, respectively, while the tool rotational speed varied from 1000 to 1400 rpm. The increase of the rotational speed to 1400 rpm resulted in degradation of the mechanical properties. The stir zone grain structure was refined; however, the grain size was irregular. Grain refining occurs due to a continuous and discontinuous dynamic recrystallization mechanism. In the grain interior, there were many large dislocations, identifying that incomplete recrystallization took part within the SZ. Instead, the lower rotational speed, i.e., 1000 rpm, led to more uniform grain refinement in the SZ. Moreover, in contrast to the welded zone where very fine grains exist, the base metal and thermomechanically heat-affected zone display coarser grains. Because of the microstructural modification, the stir zone’s mechanical characteristics were higher than the base materials, and the mechanical strength and plasticity were simultaneously upgraded. These results indicate that the size of the grains is independent of rotational speed. And mechanical properties like hardness and impact strength decreased as the rotational speed increased.

[1]  Rajneesh Sharma,et al.  Influence of Planetary Ball Mill Parameters on Powder Flowability of AlSi10Mg with Niobium Carbide Using Central Composite Design (CCD) , 2022, Advances in Materials Science and Engineering.

[2]  S. Raghuraman,et al.  Processing of Aluminium-Silicon Alloy with Metal Carbide as Reinforcement through Powder-Based Additive Manufacturing: A Critical Study , 2022, Scanning.

[3]  P. Asadi,et al.  Modeling of material flow in dissimilar friction stir lap welding of aluminum and brass using coupled Eulerian and Lagrangian method , 2021, The International Journal of Advanced Manufacturing Technology.

[4]  G. Çam,et al.  Formation of weld defects in cold metal transfer arc welded 7075-T6 plates and its effect on joint performance , 2019, IOP Conference Series: Materials Science and Engineering.

[5]  T. Küçükömeroğlu,et al.  Investigation of mechanical and microstructural properties of friction stir welded dual phase (DP) steel , 2019, IOP Conference Series: Materials Science and Engineering.

[6]  P. Asadi,et al.  Optimization of microstructural and mechanical properties of friction stir welded A356 pipes using Taguchi method , 2019, Materials Research Express.

[7]  T. Küçükömeroğlu,et al.  Investigation of microstructure and mechanical properties of friction stir welded dissimilar St37/St52 joints , 2019, Materials Research Express.

[8]  N. Kashaev,et al.  Prospects of laser beam welding and friction stir welding processes for aluminum airframe structural applications , 2018, Journal of Manufacturing Processes.

[9]  N. Arivazhagan,et al.  Investigation of metallurgical and mechanical properties of 21st century nickel-based superalloy 686 by electron beam welding technique , 2018, Sādhanā.

[10]  R. Valiev,et al.  Review on superior strength and enhanced ductility of metallic nanomaterials , 2018 .

[11]  Gürel Çam,et al.  Recent developments in joining of aluminum alloys , 2017 .

[12]  M. Manikandan,et al.  Analysis of Metallurgical and Mechanical Properties of Continuous and Pulsed Current Gas Tungsten Arc Welded Alloy C-276 with Duplex Stainless Steel , 2017, Transactions of the Indian Institute of Metals.

[13]  H. Kokawa,et al.  Tensile behavior of friction-stir welded AZ31 magnesium alloy , 2017 .

[14]  M. Emamy,et al.  Wear Behavior of Al/CMA-Type Al3Mg2 Nanocomposites Fabricated by Mechanical Milling and Hot Extrusion , 2016 .

[15]  Z. Ma,et al.  Low cycle fatigue properties of friction stir welded joints of a semi-solid processed AZ91D magnesium alloy , 2014 .

[16]  J. Jonas,et al.  Dynamic and post-dynamic recrystallization under hot, cold and severe plastic deformation conditions , 2014 .

[17]  Salar Salahi,et al.  Microstructural Refinement of Pure Copper by Friction Stir Processing , 2013 .

[18]  N. Gao,et al.  Enhanced strength–ductility synergy in nanostructured Cu and Cu–Al alloys processed by high-pressure torsion and subsequent annealing , 2012 .

[19]  E. Nazari,et al.  Effect of friction stir welding (FSW) parameters on strain hardening behavior of pure copper joints , 2012 .

[20]  B. Xiao,et al.  High tensile ductility via enhanced strain hardening in ultrafine-grained Cu , 2012 .

[21]  A. Davoodi,et al.  Microstructural and mechanical properties of friction stir welded Cu–30Zn brass alloy at various feed speeds: Influence of stir bands , 2011 .

[22]  Ting Zhu,et al.  Ultra-strength materials , 2010 .

[23]  S. Niknejad,et al.  An Investigation on Microstructure and Mechanical Properties of Nd:YAG Laser Beam Weld of Copper Beryllium Alloy , 2009 .

[24]  K. Lu,et al.  Strengthening Materials by Engineering Coherent Internal Boundaries at the Nanoscale , 2009, Science.

[25]  H. Bhadeshia,et al.  Recent advances in friction-stir welding : Process, weldment structure and properties , 2008 .

[26]  L. Geng,et al.  Development of a fine-grained microstructure and the properties of a nugget zone in friction stir welded pure copper , 2007 .

[27]  S. Jung,et al.  The joint properties of copper by friction stir welding , 2004 .

[28]  L. Svensson,et al.  Microstructure and mechanical properties of friction stir welded aluminium alloys with special reference to AA 5083 and AA 6082 , 2000 .

[29]  C. Meran The joint properties of brass plates by friction stir welding , 2006 .

[30]  F. Frank,et al.  On deformation by twinning , 1955 .