作者:Yongxian Huang,Yumin
页数:574页
出版社:哈尔滨工业大学出版社
出版日期:2023
ISBN:9787576705058
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内容简介
Despite short invention history traced back to 1991, sparked with their non-melting processes and high performance, friction stir welding and processing are emerging as the most state-of-the-art techniques in materials processing engineering used in the lightweight industrial products. This book is intended to give the students, engineers and researchers engaged in the field to use these newly developed solid-state welding and processing approaches. The book contains relatively broad comprehensive techniques and relative results found, including friction stir welding, friction stir processing,and deformation-driven metallurgy, to draw a clear prospect for the future of these revolutionary approaches.
作者简介
黄永宪,Is the dean of the Department ofWelding Technology and Engineering and the vice director of the State Key Laboratory ofAdvanced Welding and Joining.He received his Ph.D. degree from Harbin Institute of Technology in 2008. His research focuses on the basis and applications of friction stir welding, processing,additive manufacturing, and derived technologies. He has published 160 scientific papers and 100 granted patents. He has won provincial/ministerial level science/technology/teaching awards for 4 times.
谢聿铭,Is an assistant professor of Harbin Institute of Technology. He received his Ph.D.degree from
Harbin Institute of Technology in 2022. His research focuses on the deformation-driven metallurgy principles and numerical modelling of friction stir welding.He has published 50 scientific papers and 20 granted patents.
孟祥晨,Is an associate professor of Harbin Institute of Technology. He received his Ph.D. degree from Harbin Institute of Technology in 2020. His research focuses on the solid-state welding, additive manufacturing,and remanufacturing of lightweight and dissimilar materials. He has published 100 scientific papers and 20 granted patents.
目录
1.1 Friction stir welding
1.2 Friction stir processing
1.3 Deformation-driven metallurgy
References
Chapter 2 Self-supported friction stir welding
2.1 Introduction
2.2 Bobbin tool friction stir welding
2.3 Penetrating friction stir welding
2.4 Self-support friction stir welding
2.5 Plastic deformation analysis of SSFSW1 joint
2.6 Prospects
References
Chapter 3 Non-weld-thinning friction stir welding
3.1 Stationary shoulder friction stir welding
3.2 Additive friction stir welding
3.3 Zero-plunge-depth friction stir welding
References
Chapter 4 Friction stir-based remannfacturing
4.1 Background
4.2 Principle and advantages
4.3 Types of FSW defects
4.4 Repetitive friction stir remanufacturing
4.5 Additive friction stir remanufacturing
4.6 Prospects
References
Chapter 5 High depth-to-width ratio friction stir welding
5.1 Numerical design of high depth-to-width ratio friction stir welding
5.2 Joint formation mechanism of high depth-to-width ratio friction stir welding
5.3 Grain growth behavior of high depth-to-width ratio friction stir welding
References
Chapter 6 Entire-process simulation of friction stir welding
6.1 Experiments and simulation
6.2 Implementation of neural networks
References
Chapter 7 Surface modification via friction stir processing
7.1 Surface composite fabricated by direct friction stir processing
7.2 Cryogenic surface-grinding assisted friction stir processing
7.3 Arc surface-nitriding assisted friction stir processing
References
Chapter 8 Friction stir processed bulk materials
8.1 Microstructural evolution and mechanical properties of Mg-Zn-Y-Zr alloy during friction stir processing
8.2 Dynamic recrystallization and mechanical properties of friction stir processed Mg-Zn-Y-Zr alloys
8.3 Uhrafine-grained Mg-Zn-Y-Zr alloy with remarkable improvement in superplasticity
8.4 Enhanced strength and ductility of friction-stir-processed Mg-6Zn alloys via Y and Zr co-alloying
8.5 Strengthening and toughening mechanisms of CNTs/Mg-6Zn composites via friction stir processing
References
Chapter 9 Graphene nanoplatelet-reinforced aluminum matrix composites
9.1 Feasibility verification of deformation-driven metallurgy
9.2 Ameliorating strength-ductility efficiency of graphene nanoplatelet- reinforced aluminum composites
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