Reprint
Advances in Hard-to-Cut Materials
Manufacturing, Properties, Process Mechanics and Evaluation of Surface Integrity
Edited by
March 2020
222 pages
- ISBN978-3-03928-354-5 (Paperback)
- ISBN978-3-03928-355-2 (PDF)
This is a Reprint of the Special Issue Advances in Hard-to-Cut Materials: Manufacturing, Properties, Process Mechanics and Evaluation of Surface Integrity that was published in
Chemistry & Materials Science
Engineering
Physical Sciences
Summary
The rapid growth of modern industry has resulted in a growing demand for construction materials with excellent operational properties. However, the improved features of these materials can significantly hinder their manufacture and, therefore, they can be defined as hard-to-cut. The main difficulties during the manufacturing/processing of hard-to-cut materials are attributed especially to their high hardness and abrasion resistance, high strength at room or elevated temperatures, increased thermal conductivity, as well as resistance to oxidation and corrosion. Nowadays, the group of hard-to-cut materials is extensive and still expanding, which is attributed to the development of a novel manufacturing techniques (e.g., additive technologies). Currently, the group of hard-to-cut materials mainly includes hardened and stainless steels, titanium, cobalt and nickel alloys, composites, ceramics, as well as the hard clads fabricated by additive techniques. This Special Issue, “Advances in Hard-to-Cut Materials: Manufacturing, Properties, Process Mechanics and Evaluation of Surface Integrity”, provides the collection of research papers regarding the various problems correlated with hard-to-cut materials. The analysis of these studies reveals the primary directions regarding the developments in manufacturing methods, characterization, and optimization of hard-to-cut materials.
Format
- Paperback
License and Copyright
© 2020 by the authors; CC BY-NC-ND license
Keywords
magnesium; alloying; spark plasma sintering; elastic modulus; corrosion resistance; bioactivity; additive manufacturing; SLM technology; porosity research; microhardness research; drilling; dynamometer; hole quality; forces; roundness; roughness; wear; chips; burr; abrasive machining; sapphire substrate; resin bond; surface; texture; machining; multiscale; aluminum alloy 6061 T6; surface finish; high speed milling (HSM); roughness; modeling; intelligent optimization; hard turning; surface roughness; cutting temperature; evolutionary algorithm; Ti-6Al-4V; alloy; EDC; microcracks; microhardness; adhesion strength; fused deposition modelling; investment casting; mathematical modelling; aluminium matrix composite; environmentally friendly; nano-cutting fluids; nickel-based alloys; turning; optimization; micro-groove; titanium alloy; surface integrity; material swelling and springback; ultrasonic elliptical vibration assisted cutting; artificial neural network; prediction; tool wear; ultrasonically assisted turning; Nimonic-90; surface roughness; power consumption; optimization; nature inspired hybrid algorithm; hard–to–cut materials; machining; additive manufacturing; mechanics; surface integrity