This collection presents fundamentals and the current status of friction stir welding (FSW) and solid-state friction stir processing of materials, and provides researchers and engineers with an opportunity to review the current status of the friction stir related processes and discuss the future possibilities. Contributions cover various aspects of friction stir welding and processing including their derivative technologies. Topics include but are not limited to:
derivative technologies
high-temperature lightweight applications
industrial applications
dissimilar alloys and/or materials
controls and nondestructive examination
simulation
characterization
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Part I Lightweight Materials and High Entropy Alloys |
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Case Study: Implementation of FSW in the Colombian Rail Transport Sector |
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3 | (10) |
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Three-Sheet AI Alloy Assembly for Automotive Application |
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13 | (8) |
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Characterization and Analysis of Effective Wear Mechanisms on FSW Tools |
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21 | (14) |
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Friction Stir Lap Welding Between Al and FeCoCrNiMn High Entropy Alloy |
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35 | (8) |
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Modified Friction Stir Welding of AI-Zn-Mg-Cu Aluminum Alloy |
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43 | (12) |
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Part II High Melting Temperature Materials |
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Low-Force Friction Surfacing for Crack Repair in 304L Stainless Steel |
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55 | (14) |
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Part III Control and Non-destructive Examination |
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Real-Time Measurement of Friction Stir Tool Motion During Defect Interaction in Aluminum 6061-T6 |
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69 | (12) |
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Preliminary Investigation of the Effect of Temperature Control in Friction Stir Welding |
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81 | (10) |
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Transitioning FSW to a Controlled Production Process |
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91 | (14) |
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Removing Rotational Variations from Shoulder Thermocouples in Friction Stir Welding |
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105 | (10) |
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Dissimilar Joining of ZEK100 and AA6022 for Automotive Application |
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115 | (10) |
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Fracture Mechanics Approach to Improve Fatigue Strength of a Dissimilar Metal T-Lap Joint by Friction Stir Welding |
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125 | (10) |
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Effect of Diffusion on Intermetallics at Interface During Friction Stir Welding of Stainless Steel and Pure Titanium |
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135 | (14) |
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Part V Derivative Technologies for Dissimilar |
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Process Robustness of Friction Stir Dovetailing of AA7099 to Steel with In Situ AA6061 Interlayer Linking |
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149 | (12) |
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Part VI Modeling: Process and Properties |
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The Development of FSW Process Modelling for Use by Process Engineers |
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161 | (10) |
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Effect of Tool Geometries on "Heat-Input" During Friction Stir Welding of Aluminum Alloys |
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171 | (8) |
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Experimental and Numerical Investigations of High Strain Rate Torsion Tests of AI-Based Alloys at Elevated Temperatures |
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179 | (10) |
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Part VII Spot Technologies |
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Advances in Refill Spot Welding Productivity |
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189 | (10) |
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Characterization of Intermetallics Formation in U.FSSW of Dissimilar Al/Cu Alloy Sheets |
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199 | (10) |
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Temperature Distribution During Friction Stir Spot Welding of Thin AA 6082-T6 and AA 5082-O Sheets |
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209 | (10) |
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| Author Index |
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219 | (2) |
| Subject Index |
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221 | |
Dr. Yuri Hovanski, Brigham Young University; Dr. Piyush Upadhyay, Pacific Northwest National Laboratory; Dr.Yutaka Sato, Tohoku University, Japan; Dr. Nilesh Kumar, The University of Alabama; Dr. Anton A. Naumov, Peter the Great St. Petersburg Polytechnic University, Russia.
Lisainfo e-raamatute kohta