Reprint
Advances in Plastic Forming of Metals
Edited by
October 2018
282 pages
- ISBN978-3-03897-260-0 (Paperback)
- ISBN978-3-03897-261-7 (PDF)
This is a Reprint of the Special Issue Advances in Plastic Forming of Metals that was published in
Chemistry & Materials Science
Engineering
Summary
The forming of metals through plastic deformation comprises a family of methods that produce components through the re-shaping of input stock, oftentimes with little waste. Therefore, forming is one of the most efficient and economical manufacturing process families available. A myriad of forming processes exist in this family. In conjunction with their countless existing successful applications and their relatively low energy requirements, these processes are an indispensable part of our future. However, despite the vast accumulated know-how, research challenges remain, be they related to the forming of new materials (e.g., for light-weight transportation applications), pushing the boundaries of what is doable, reducing the intermediate steps and/or scrap, or further enhancing the environmental friendliness. The purpose of this book is to collect expert views and contributions on the current state-of-the-art of plastic forming, thus highlighting contemporary challenges and offering ideas and solutions.
Format
- Paperback
License and Copyright
© 2019 by the authors; CC BY license
Keywords
30Cr2Ni4MoV steel; hot deformation; processing map; microstructure; hydrostatic extrusion; FEA; pressure load; die angle; extrusion ratio; deformation behavior; constitutive model; BP neural network; aluminum alloy; isothermal forging; design; FEM; ECAP; DOE; plasticity modeling; kinematic hardening; plastic anisotropy; finite element simulation; ultra-low cycle fatigue; failure; strain evolution; U-bending; pad; finite element method; spring-back; analysis of variance (ANOVA); magnesium metal matrix composites (Mg MMCs); extrusion; annealing; mechanical properties; AHSS; dual-phase steels; cold extrusion; multi-pass dies; damage; central burst; finite element analysis (FEA); anisotropy; bending; numerical simulation; sheet metal forming; springback; shape memory alloy (SMA); NiTiFe alloy; grain refinement; equal-channel angular extrusion (ECAE); microstructure; modeling; simulation; sheet metal; necking; damage; forming limit diagrams; deep drawing test; sheet-metal forming; stretch-bending; necking; maximum force criterion; bending effect; anisotropy; combined isotropic–kinematic hardening; dual-phase steel; multi-point dieless forming; springback reduction; springback compensation; radial basis function; formability; failure; sheet metal forming; Single-Point Incremental Forming (SPIF); advanced high-strength steel; yield function; hardening model; springback; deformation mode; friction; sliding; upsetting; fine grain layer; hot forging; finite-element; oxide scale; n/a