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181   $ctxt$2rdacontent
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200 10$aHybrid manufacturing processes $ephysical fundamentals, modelling and rational applications /$fWit Grzesik, Adam Ruszaj
210  1$aCham, Switzerland :$cSpringer,$d[2021]
210  4$d©2021
215   $a1 online resource (247 pages)
225 1 $aSpringer Series in Advanced Manufacturing
311   $a3-030-77106-7 
327   $aIntro -- Preface -- Contents -- Symbols and Abbreviations -- Latin Symbols -- Greek Symbols -- Abbreviations -- 1 General Characteristics of Material Shaping Processes -- 1.1 Classification of Material Removal Processes -- 1.2 Classification of Additive Processes -- References -- 2 Classification of Hybrid Machining Processes Generating by Different Rules -- 2.1 Classification Criteria and Systems -- 2.2 Generation of Hybrid Conventional and Unconventional Processes -- 2.3 Survey of Hybrid Machining Processes -- 2.3.1 Hybrid Assisted Processes -- 2.3.2 Hybrid Combined Processes -- References -- 3 Application of Hybrid Machining Processes in Industry -- 3.1 Role of Hybrid Machining Processes in Sustainable Manufacturing and Production 4.0 Strategy -- 3.2 Application Areas of Hybrid Machining Processes in Various Industry Sectors -- 3.3 Applications of Hybrid Micro and Nano-Machining Processes -- 3.4 Future Vision of Hybrid Manufacturing Processes -- References -- 4 Physical Fundamentals of Conventional and Unconventional Machining Processes -- 4.1 Physical Phenomena in the Zone of Machining Processes -- 4.1.1 Cutting Processes -- 4.1.2 Abrasive Processes -- 4.1.3 Electrodischarge Machining (EDM) -- 4.1.4 Electrochemical Machining (ECM) -- 4.1.5 Water Jet and Abrasive Water Jet Machining Processes -- 4.1.6 Laser Beam Machining Process -- 4.1.7 Ion Beam and Electron Beam Machining Processes -- 4.2 Characterization of Mechanical Influence on the Workpiece Material -- 4.3 Characterization of Thermal Influence on the Workpiece Material -- 4.4 Constitution of Subsurface Layer of the Workpiece Material -- 4.5 Possibilities of Controlling Surface Layer Properties by Means of Hybrid Processes -- References -- 5 Modelling of Hybrid Machining Processes -- 5.1 Models of Conventional and Unconventional Machining Processes.
327   $a5.1.1 Models of Cutting and Abrasive Processes -- 5.1.2 Models of EDM Process -- 5.1.3 Models of ECM Process -- 5.1.4 Models of LBM Process -- 5.1.5 Models of WJM Process -- 5.2 Constitutive Materials Models -- 5.3 Techniques of Determination of Material Properties Under Complex Physical Interactions -- 5.4 Modelling Techniques -- 5.4.1 Analytical Models -- 5.4.2 Numerical Modelling -- 5.4.3 Modelling Using AI Techniques -- References -- 6 Vibration-Assisted Machining Processes -- 6.1 Classification of Vibration-Assisted Machining Processes -- 6.2 Vibration-Assisted Cutting Processes -- 6.2.1 Physical and Technological Effects -- 6.2.2 Processes with the Assistance of Low Frequency Vibration (VAM) -- 6.2.3 Processes with the Assistance of Ultrasonic Vibrations (UAM)-Turning, Drilling and Milling -- 6.3 Vibration-Assisted Grinding and Polishing Processes -- 6.4 Vibration-Assisted EDM Processes -- 6.5 Vibration-Assisted ECM Processes -- 6.6 Industrial Applications of Vibration-Assisted Machining Processes -- References -- 7 Media-Assisted Machining Processes -- 7.1 Classification of Media-Assisted Machining Processes (MAM) -- 7.2 Physical, Tribological and Technological Effects -- 7.3 Fluid Media-Assisted Machining Processes -- 7.3.1 Fluid Media-Assisted Cutting Processes -- 7.3.2 Fluid Media-Assisted EDM Process -- 7.4 Cryogenic Subtractive Processes -- 7.4.1 Introduction -- 7.4.2 Machining Processes with Cooled CO2 -- 7.4.3 Cryogenic Machining Processes with Liquid Nitrogen (LN2) -- 7.5 Industrial Applications of Liquid and Gaseous-Assisted Machining Processes -- References -- 8 Magnetic and Electric Field-Assisted Machining Processes -- 8.1 Introduction -- 8.2 Magnetic Field-Assisted Finishing Processes -- 8.3 Magnetic Field-Assisted Electrodischarge Processes -- 8.4 Magnetic Field-Assisted Electrochemical Processes.
327   $a8.5 Electric Field-Assisted Processes -- References -- 9 Thermally-Assisted Machining Processes -- 9.1 Classification of Thermally-Assisted Machining Processes -- 9.2 Physical and Technological Effects -- 9.3 Laser-Assisted Machining (LAM) -- 9.3.1 Laser-Assisted Cutting Processes -- 9.3.2 Laser-Assisted Grinding Processes -- 9.3.3 Laser-Assisted WJM Process -- 9.3.4 Laser-Assisted EDM Processes -- 9.3.5 Laser-Assisted ECM Processes -- 9.4 Plasma-Assisted Machining (PAM) Processes -- 9.5 Industrial Applications of Thermally-Assisted Machining Processes -- References -- 10 Mixed Hybrid Processes -- 10.1 Classification of Hybrid Machining Methods -- 10.2 Combination of Subtractive Conventional Processes -- 10.2.1 Turn-Milling Process -- 10.2.2 Turn-Broaching Process -- 10.3 Combination of Subtractive Conventional and Non-conventional Processes -- 10.3.1 Electro-Discharge Grinding (EDG) -- 10.3.2 Electrochemical Grinding (ECG) and Finishing -- 10.3.3 Electrochemical Finishing -- 10.4 Combination of Subtractive Non-conventional Processes -- References -- 11 Hybrid Processes with Controlled Mechanisms -- 11.1 Classification of Hybrid Machining Methods -- 11.2 Synergetic Physical and Technological Effects -- 11.3 Grind Hardening and Strengthening -- 11.4 Combination of Rolling and Cryogenic Hardening -- 11.5 Combination of Subtractive and Transformative Processes (Sequential Cutting and Burnishing Processes) -- 11.6 Industrial Applications of Machining Processes with Controlled Mechanisms -- References -- 12 Hybrid Additive and Subtractive Processes -- 12.1 Applications of Different Additive Technologies and Subtractive Processes -- 12.1.1 Introduction -- 12.1.2 Layer Deposition Techniques in Additive Processes -- 12.2 Special Multi-axis Manufacturing Platforms for Hybrid Additive-Subtractive Processes.
327   $a12.2.1 Constructions of Integrated Modular Manufacturing Platforms -- 12.2.2 Programming of Multi-axis Hybrid Machining Processes -- 12.3 Repair and Renovation Technologies -- 12.4 Development Trends in Hybrid Additive-Subtractive Processes -- References -- 13 Economics and Optimization Strategies of Hybrid Processes -- 13.1 Optimization Criteria and Models -- 13.2 Optimization Criteria and Algorithms for the Selection of Machining Conditions -- 13.3 Optimization Fundamentals -- References -- 14 Influence of Process Hybridization on Surface Integrity -- 14.1 Structural Models of Subsurface Layer -- 14.2 Characteristics of Surface Roughness in Different Hybrid Machining Processes -- 14.3 Physical Properties of Subsurface Layer -- 14.3.1 Characteristics of Physical Properties of Subsurface Layer -- 14.3.2 Residual Stresses in Subsurface Layer -- 14.3.3 Strain-Hardening Effect in the Subsurface Layer -- 14.3.4 Changes of Material Microstructure and Surficial Defects -- References.
410  0$aSpringer series in advanced manufacturing.
606   $aManufacturing processes
615  0$aManufacturing processes.
676   $a670
700   $aGrzesik$b Wit$0878249
702   $aRuszaj$b Adam
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910488727003321
996   $aHybrid Manufacturing Processes$92569174
997   $aUNINA