Reprint
Forming Processes of Modern Metallic Materials
Edited by
October 2020
258 pages
- ISBN978-3-03943-156-4 (Hardback)
- ISBN978-3-03943-157-1 (PDF)
This book is a reprint of the Special Issue Forming Processes of Modern Metallic Materials that was published in
Chemistry & Materials Science
Engineering
Summary
The plastic forming of metallic materials is the most efficient and an important manufacturing technology in today's industry. Lightweight materials, such as titanium alloys, aluminum alloys, and ultra-high-strength steels, are used extensively in the automotive, aerospace, transportation, and construction industries, leading to increased demand for advanced innovative forming technologies. Today, numeric simulations are highly focused and provide a better understanding of the innovative forming processes. Computational methods and numerical analysis coupled with the modelling of the structural evolution allow us to reduce time costs and eliminate experimental tests. The subjects of research articles published in this nook are multidisciplinary, including friction and lubrication in sheet metal forming, hot strip rolling and tandem strip rolling, application of numeric methods to simulate metal forming processes, development of new creep performance materials, the single point incremental forming process, and the fatigue fracture characteristics of Alclad 7075-T6 aluminum alloy sheets joined by refill friction stir spot welding. Review articles summarize the approaches on the innovative numerical algorithms, experimental methods, and theoretical contributions that have recently been proposed for sheet metal forming by researchers and business research centers.
Format
- Hardback
License
© 2020 by the authors; CC BY-NC-ND license
Keywords
electromagnetically assisted forming; springback control; numerical simulation; modified 9Cr-2W steel; B content; phase transformation; texture; heat treatment; coefficient of friction; deep drawing; draw bead; material properties; sheet metal forming; surface properties; drawbead; FEM; friction; material properties; numerical modeling; mechanical engineering; sheet metal forming; stamping process; coefficient of friction; bending under tension; draw bead; friction; friction testing; material properties; mechanical engineering; sheet metal forming; strip drawing; surface properties; tribology; tandem skew rolling; seamless tube; magnesium alloy; deformation behavior; high strength steel; asymmetric rolling; aluminum alloy; planar anisotropy; mechanical properties; microstructures; mechanical engineering; truncated cone; incremental sheet forming; SPIF; bending under tension test; BUT; coefficient of friction; friction; material properties; mechanical engineering; sheet metal forming; aircraft industry; aluminium alloy; friction stir spot welding; mechanical engineering; single-lap joints; bending force prediction; hot strip rolling (HSR); comparative assessment; machine learning; regression; electromagnetic forming; finite element method; flexible-die forming; flow-forming; incremental sheet forming; mechanical engineering; metal forming; numerical modeling; plastic working; sheet metal forming; solid granular medium forming; spinning; warm forming; n/a