𝔖 Scriptorium
✦   LIBER   ✦
πŸ“

Advanced manufacturing and processing technology

✍ Scribed by byChander Prakash, Sunpreet Singh, J. Paulo Davim (editors)

Publisher
CRC Press
Year
2020
Tongue
English
Leaves
245
Category
Library
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✦ Synopsis

"This book disseminates recent research, theories, and practices relevant to areas of surface engineering and processing of materials for functional application such as aerospace, automobile, and biomedical. The book focuses on the hidden technologies and advanced manufacturing methods which may not be standardized by the research fraternity, however, are greatly beneficial to the material and manufacturing industrial engineers in different aspects. It provides such projects, research activities, and innovations on a global platform to strengthen the knowledge of the concerned community. The book covers surface engineering including coating, deposition, cladding, nanotechnology, surface finishing, precision machining, processing, and emerging advanced manufacturing technologies to enhance the performance of materials in terms of corrosion, wear and fatigue. The book has capture emerging areas of materials science and advanced manufacturing engineering and presents the recent trends in research for young researchers, field engineers, and academic professionals"--

✦ Table of Contents

Cover
Half Title
Series Page
Title Page
Copyright Page
Table of Contents
Preface
Editors
Contributors
Chapter 1 A Critical Review on the Machining of Engineering Materials by Die-Sinking EDM
1.1 Introduction
1.2 Researches on Electrical Discharge Machining Process
1.2.1 Researches on Enhancement of Tool Wear
1.2.2 Optimization of Process Parameters
1.2.3 Selection of Electrode Material
1.2.4 Multispark Erosion Studies
1.2.5 Selection of Optimized Pulse Duration
1.2.6 Vibratory Tool and Workpiece
1.2.7 Introducing Servo Control Mechanism
1.2.8 Magnetic Field–Based Electrical Discharge Machining
1.2.9 Special Tools
1.2.10 CNC-Controlled Electrical Discharge Machining
1.2.11 Selection of Dielectric Medium
1.3 Application of Electrical Discharge Machining for Biomaterials
1.4 Conclusions
References
Chapter 2 Optimization of Machining Parameters of High-Speed Toolpath to Achieve Minimum Cycle Time for Ti-6Al-4V
2.1 Introduction to High-SpeedMachining
2.2 Experimental Setup
2.2.1 Selection of Material
2.2.2 Job Setup on Machine
2.2.3 Machine Specifications
2.2.4 High Helix Cutter
2.2.5 Machining Strategy: Dynamic Cutting Strategy from
Mastercam Software
2.2.6 Selection of Parameters
2.2.7 Design of Experimentation
2.2.8 Results from Response Surface Methodology
2.3 Results and Discussions
2.3.1 Effect of Process Parameters on the Spindle Load
2.3.2 Effect of the Process Parameters on Cycle Time
2.4 Conclusion
References
Chapter 3 A Review of Machinability Aspects of Difficult-to-Cut Materials Using Microtexture Patterns
3.1 Introduction
3.1.1 Judging Machinability
3.1.1.1 Tool Life
3.1.1.2 Power Consumption
3.1.1.3 Surface Finish
3.1.1.4 Chip Form
3.1.2 Difficult-to-Cut Material
3.1.3 Compilation of Machining Technologies
3.1.4 Various Steps Taken to Solve Issues
3.1.4.1 Hot Machining
3.1.4.2 Minimum Quantity of Lubricant
3.1.4.3 Coated Tools
3.1.4.4 High-SpeedMachining
3.1.4.5 Flood Cooling
3.1.4.6 Microgrooves
3.2 Literature Review
3.3 Discussion and Future Work
3.4 Conclusions
References
Chapter 4 Micromachining
4.1 Introduction
4.2 Conventional Micromachining
4.3 Nonconventional Micromachining
4.3.1 Ultrasonic Micromachining
4.3.1.1 Working Principle
4.3.1.2 Tool Material
4.3.1.3 Tool Feed Mechanism
4.3.1.4 Abrasive Slurry System
4.3.1.5 Oscillating System
4.3.1.6 Process Parameters
4.3.1.7 Effect of Process Parameters on Material Removal Rate
4.3.1.8 Advantages
4.3.1.9 Limitations
4.3.1.10 Applications
4.3.2 Abrasive Jet Micromachining
4.3.2.1 Working Principle
4.3.2.2 Process Parameters
4.3.2.3 Abrasive Material
4.3.2.4 Gas Medium
4.3.2.5 Nozzle
4.3.2.6 Effect of Material Removal Rate
4.3.2.7 Advantages
4.3.2.8 Limitations
4.3.2.9 Applications
4.3.3 Electrochemical Micromachining
4.3.3.1 Working Principle
4.3.3.2 Process Parameters
4.3.3.3 General Material Removal Rate Model for Electrochemical Micromachining
4.3.3.4 Advantages
4.3.3.5 Limitations
4.3.3.6 Applications
4.3.4 Electrodischarge Micromachining
4.3.4.1 Working Principle
4.3.4.2 Components of Electrodischarge Micromachining
4.3.4.3 Process Parameters
4.3.4.4 Variants of Electrodischarge Micromachining
4.3.4.5 Advantages
4.3.4.6 Limitations
4.3.4.7 Applications
4.3.5 Laser Beam Micromachining
4.3.5.1 Working Principle
4.3.5.2 Mechanism of Material Removal
4.3.5.3 Laser Mask Projection Technique
4.3.5.4 Effect of Laser Beam Intensity
4.3.5.5 Material Removal Rate in Pulsed Laser
4.3.5.6 Advantages
4.3.5.7 Limitations
4.3.5.8 Applications
4.3.6 Electron Beam Micromachining
4.3.6.1 Working Principle
4.3.6.2 Electron Beam Micromachining Equipment
4.3.6.3 Components of Electron Beam Micromachining
4.3.6.4 Process Parameters
4.3.6.5 Advantages
4.3.6.6 Limitations
4.3.6.7 Applications
4.3.7 Plasma Arc Micromachining
4.3.7.1 Working Principle
4.3.7.2 Process Parameter
4.3.7.3 Advantages
4.3.7.4 Limitations
4.3.7.5 Applications
4.4 Conclusions and Future Study
References
Chapter 5 A Review Study on Miniaturizationβ€”A Boon or Curse
5.1 Introduction
5.2 Recent Studies
5.2.1 Process Physics
5.2.2 Minimum Chip Thickness and Specific Cutting Energy
5.2.3 Ductile Mode Machining
5.2.4 Edges and Surface Finish
5.2.5 Workpiece and Design Issues
5.2.6 Machines, Tools, and Systems for Micromachining
5.2.7 Cutting Fluid
5.2.8 Machine Components and Controls
5.2.9 Metrology in Micromachining
5.3 Conclusion and Brief Discussion
5.4 Future Scope
References
Chapter 6 A Comprehensive Review on Similar and Dissimilar Metal Joints by Friction Welding
6.1 Introduction
6.2 Friction Welding between Ferrous and Nonferrous Metal Alloys
6.3 Friction Welding between Ferrous Metal Alloys
6.4 Friction Welding between Nonferrous Metal Alloys
6.5 Finite Element Model in Friction Welding
6.6 Conclusion
References
Chapter 7 3D Bioprinting in Pharmaceuticals, Medicine, and Tissue Engineering Applications
7.1 Introduction
7.2 3D Printing in Pharmaceuticals
7.3 3D Printing in Medicine
7.3.1 Materials
7.3.2 In situ 3D Bioprinting
7.3.2.1 Biomimicry
7.3.2.2 Independent Self-Assembly
7.3.2.3 Miniature Tissue Blocks
7.3.3 Bioscaffolding
7.4 Conclusion
References
Chapter 8 Investigating on the Lapping and Polishing Process of Cylindrical Rollers
8.1 Introduction
8.2 Fundamental Principle
8.3 Experimental Models to Determine Friction Coefficient in Machining
8.3.1 Setup and Conditions for Lapping Process
8.3.2 Setup and Conditions for Polishing Process
8.4 Effects of Experimental Conditions on the Friction Coefficients
8.4.1 Lapping Process with SiC Abrasive Slurry
8.4.2 Polishing Process with Al(2)O(3) Abrasive Slurry
8.5 Experimental Results for Lapping Process
8.5.1 Experimental Setup
8.5.2 Effect of Abrasive Size to Surface Roughness of Cylindrical Roller
8.5.3 Effect of Downforce to Surface Roughness of Cylindrical Roller
8.5.4 Effect of Downforce to Material Removal Rate of Cylindrical Roller
8.5.5 Effect of Downforce to Roundness of Cylindrical Roller
8.6 Experimental Results for Polishing Process
8.6.1 Experimental Setup
8.6.2 Effect of Abrasive Size to Surface Roughnessof Cylindrical Roller
8.6.3 Effect of Downforce to Surface Roughness of Cylindrical Roller
8.6.4 Effect of Downforce to Material Removal Rate of Cylindrical Roller
8.6.5 Effect of Downforce to Roundness of Cylindrical Roller
8.7 Conclusion
References
Chapter 9 NiTi Thin-Film Shape Memory Alloys and Their Industrial Application
9.1 Historical Background of Shape Memory Alloys
9.2 What Is Unique about NiTi Alloy?
9.3 Stress–Strain–Temperature Curve of a NiTi
9.4 Physical Metallurgy of NiTi Thin Film
9.4.1 Phase Diagram
9.4.2 Martensitic Transformation and Crystallography
9.5 Physical Properties of the NiTi Thin Film
9.5.1 Field-EmissionScanning Electron Microscopy
9.5.2 Grazing Incidence X-RayDiffraction
9.5.3 High-Resolution Transmission Electron Microscopy
9.6 Applications of Shape Memory Alloys
9.6.1 Microvalves and Micropumps
9.6.2 Microgripper and Microtweezer
9.6.3 Biomedical Equipment
9.7 Advantages and Limitations of NiTi Thin Film
9.8 Conclusions
References
10 Carbon Fibers: Surface Modification Strategies and Biomedical Applications
10.1 Surface Treatment
10.1.1 Surface Oxidation
10.1.2 Surface Coating
10.2 Applications of Carbon Fibers
10.2.1 Carbon Fibers and Composite Implant for Bone
10.2.2 Carbon Fiber in Tissue Growth
10.2.3 Dental Implants
10.2.4 Regenerative Medicine
10.2.5 Carbon Fibers in Drug Delivery
10.2.6 Carbon Fibers in Biomedical Sensor
10.2.7 Carbon Fibers Composites
10.3 Summary
References
Index

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