Advances in the Experimentation and Numerical Modeling of Material Joining Processes

doi:10.3390/books978-3-03928-591-4

Reprint

Download Flyer

Advances in the Experimentation and Numerical Modeling of Material Joining Processes

Edited by

January 2024

398 pages

ISBN978-3-03928-592-1 (Hardback)
ISBN978-3-03928-591-4 (PDF)

https://doi.org/10.3390/books978-3-03928-591-4

Free download (PDF)

This book is a reprint of the Special Issue Advances in the Experimentation and Numerical Modeling of Material Joining Processes that was published in

Chemistry & Materials Science

Engineering

Physical Sciences

Summary

“Advances in the Experimentation and Numerical Modeling of Material Joining Processes" is an innovative compilation offering a comprehensive exploration of the latest developments in material-joining techniques. With 22 chapters, this MDPI scientific reprint addresses adhesive bonding, welding, friction stir welding, hybrid joining, and miscellaneous topics. The editorial (Chapter 1) provides the main limitations, possible improvements, active research lines, and prospects of material joining processes. Chapters 2 to 10 relate to adhesive bonded and welded joints. Chapters 11 to 17 shift the focus to friction stir welding, covering the aerospace industry's progress, microstructure analysis, tool tilt angles, and corrosion behaviour. Hybrid joining processes are the topic of chapters 18 and 19, discussing numerical simulation of laser–arc hybrid welding and steel–aluminium joints made by resistance spot welding. Chapters 20 to 22 explore miscellaneous topics, including interpenetrating phase composites and concrete blocks in seismic areas. This volume serves as a vital resource for researchers, engineers, and practitioners, enabling a deeper understanding of material-joining techniques and inspiring further innovation.

Format

Hardback

License

Keywords

BOA; multi-objective optimization; residual stresses; response surface method; welding distortion; bobbin tool; friction stir welding; dissimilar; intermetallic; microhardness; microstructure; precipitates; hardness; surface roughness; corrosion; grain boundary; pits; molecular dynamics; TC4-TA17 alloy; radial distribution function; phase transition; diffusion coefficient; resistance spot welding; finite difference method; real-time simulation; digital twin; sustainable materials; wood chips; theoretical study; concrete blocks; structural elements; dual-adhesive; triple-adhesive; double-sided adhesive tape; DIC; SLJ; probeless friction stir spot welding; dissimilar weld; numerical analysis; material flow; microstructure; 9%Ni steel; Ni-based austenitic filler metal; matching ferritic filler metal; preheating; post-weld heat treatment; microstructure; mechanical mismatching; hybrid joining of dissimilar materials; spot resistance welding; adhesive bonding; load-carrying capacity of joint; machine learning; neural network simulation; carbon fiber fabric; ultrasonic welding; lap joint; PEEK; prepreg; interface; adhesion; structural integrity; additive manufacturing; characteristic microstructure; steel−based materials; phase transformation; heat treatment; duplex steel; HLAW + SAW welded joint; microstructure; mechanical properties; friction stir welding; aerospace industry; SSFSW; BTFSW; RFSSW; aluminum–lithium alloys; gas metal arc welding; metal-cored wire; metal transfer; alkali element; current path; metal vapor; friction stir spot welding; numerical modeling; refill friction stir spot welding; thermal cycles; simulation of joining processes; material flow; thermomechanical characteristics; solid-state welding; polymer friction welding; polymer welded joints; RFW; dissimilar polymer welds; numerical simulation; laser–arc; interaction; welding; tool tilt angle; friction stir welding; AA 1050; mechanical properties; welding parameters; microstructure; AlZnMg alloys; extrusion welding; porthole die geometry; welding conditions; seam weld quality; Al₂O₃3D/5083Al; numerical simulation; Infiltration; solidification; ProCAST; n/a