Tribology in manufacturing technology

This book aims to show how tribological concepts can be applied in order to improve manufacturing technology in modern industry. It can be used as a guide book for engineering students or a reference useful for academics in the fields of tribology, manufacturing, materials and mechanical engineering.

Preface 1 Tribology of cutting tools 1.1 What is the tribology of cutting tools? 1.1.1 Tribology of metal cutting 1.1.2 Tribology of cutting tools 1.1.3 Importance of the subject 1.1.4 Why now? 1.2 Underlying principle 1.3 Tribological interfaces: tool-chip interface 1.3.1 Geometry of tool-chip interface 1.3.2 Summary of tribological conditions at the tool chip interface 1.3.3 System consideration 1.3.4 Stress distribution and mean 1.3.5 Temperature 1.3.5.1 Known facts 1.3.5.2 Contradiction 1.3.5.3 Moving chip - the governing equation 1.3.5.4 Summary of temperature consideration 1.3.5.5 Optimal cutting temperature law 1.3.6 Issues to be addressed 1.3.6.1 FEM modeling of contact stress distributions 1.3.6.2 Particularities of stress distribution on the restricted tool-chip contact lenght 1.3.6.3 Influence of cutting speed 1.4 Tribological interfaces: tool-workpiece interface 1.5 Tool wear 1.6 Improvements of tribological conditions of cutting tools 1.6.1 Grades of tool materials 1.6.1.1 Basic properties of tool materials 1.6.1.2 Selection of application specific grade of HSS 1.6.2 Application of the metal working fluid (MWF) through the cutting tool References 2 Tribology of machining 2.1 Friction interactions in machining 2.2 Cutting, ploughing and sliding interactions (after Jackson and Morrel, 2011) 2.2.1 Static friction and stick-slip phenomena 2.2.2 Sliding friction 2.2.2.1 Models for sliding friction 2.2.3 Friction heating 2.3 Lubrication to control friction in machining (after Jackson and Morrel, 2011) 2.3.1 Liquid lubrification References 3 Tribology in metal forming processes 3.1 Introduction 3.2 Friction 3.3 Lubrication 3.4 Wear 3.5 Conclusion References 4 Tribology in hot rolling steel strip 4.1 Introduction 4.2 Structure of oxide scale and oxidation kinetics in pure iron and carbon steel 4.2.1 Pure iron 4.2.2 Carbon steel 4.2.2.1 800 DegreesC and above 4.2.2.2 Below 800 DegreesC 4.2.3 Structure of oxide scale and oxidation kinetics in stainless steels 4.2.4 Oxidation of stainless steels in moist atmosphere 4.2.5 Oxidation of stainless steels in hot strip rolling 4.3 Mechanical properties and thermal properties of oxide scale 4.3.1 Surface characteristics 4.3.2 Morphology on cross section 4.4 Mechanical properties and thermal properties of the oxide scale 4.4.1 Mechanical properties and measurement methodology 4.4.2 Thermal properties and the effect of oxide scale on heat transfer 4.5 Evolution of oxide scale during hot rolling 4.5.1 Oxide scale growth and deformation during finishing rolling 4.5.2 Oxide scale structures developed on hot rolled steel strip 4.5.3 Deformation and fracture behaviour of oxide scale under hot rolling conditions 4.5.3.1 Carbon steel 4.5.3.2 Stainless steels 4.6 Oxide scale involved surface roughness and its transfer during hot rolling 4.6.1 Carbon steel 4.6.2 Stainless steels 4.6.3 Numerical simulation 4.7 Evaluation of friction in hot rolling and tribological effect of oxide scale 4.7.1 Evaluation of friction in hot rolling 4.7.2 Tribological effect of oxide scale 4.7.2.1 Carbon steel 4.7.2.2 Stainless steels References 5 Micro-contact at interface between tool and workpiece in metal forming 5.1 Introduction 5.2 Micro-contact under each lubrication 5.2.1 Micro-contact under dry and thin film lubrication 5.2.2 Micro-contact under thick film lubrication 5.2.3 Micro-contact under micro-plasto-hydrodynamic lubrication 5.2.4 Micro-contact under mixed lubrication 5.3 Micro-contact at the interface between tool and workpiece in sheet metal forming 5.3.1 Direct observation of micro-contact. 5.3.2 Lubrication mechanism at interface between tool and workpiece 5.4 Micro-contact at interface between roll and sheet in cold sheet rolling 5.4.1 Inlet oil film thickness 5.4.2 Micro-contact at interface between roll and sheet 5.4.3 Estimation system for micro-contact of roled sheet in stainless steel cold rolling process 5.5 Conclusions References 6 Coatings and applications 6.1 Introduction 6.2 Plasma nitriding 6.3 Chemical vapor deposition 6.4 Physical vapor deposition 6.4.1 Deposition by vacuum evaporation 6.4.2 Cathode sputtering 6.4.3 Ion plating 6.5 Modern coatings 6.5.1 Multilayer 6.5.2 DLC-diamond-like carbon 6.5.2.1 Process of DLC coating manufacture 6.6 Coating properties References