Description
Book SynopsisTheoretical and practical interests in additive manufacturing (3D printing) are growing rapidly. Engineers and engineering companies now use 3D printing to make prototypes of products before going for full production. In an educational setting faculty, researchers, and students leverage 3D printing to enhance project-related products. Additive Manufacturing Handbook focuses on product design for the defense industry, which affects virtually every other industry. Thus, the handbook provides a wide range of benefits to all segments of business, industry, and government. Manufacturing has undergone a major advancement and technology shift in recent years.
Table of ContentsAcknowledgments; Dedication; Preface; Section I: Introductory Section; Chapter 01: From Traditional Manufacturing to Additive Manufacturing; Chapter 2: A Novice’s Guide to 3D Printing Making the Process Less Magical and More Understandable; Chapter 3: Comprehensive Project Management of High End Additive Manufacturing Equipment; Chapter 4: 3D-Printing Impacts on Systems Engineering In Defense Industry; Chapter 5: 3D Printing Design Using Systems Engineering; Chapter 6: Evaluation of Existing Modeling Software; Chapter 7: Additive Manufacturing Research and Development Needs; Chapter 8: Operational Aspects and Regulatory Gaps in Additive Manufacturing; Chapter 9: Additive Manufacturing and Its Implications for Military Ethics; Chapter 10: Additive manufacturing technologies: state of the art and trends; Chapter 11: A new global approach to design for additive manufacturing; Chapter 12: A new methodological framework for design for additive manufacturing; Section II: Technical Section; Chapter 13: Development and Implementation of Metals Additive Manufacturing; Chapter 14: Selective Laser Melting (SLM) of Ni-based Superalloys - A Mechanics of Materials Review; Chapter 15: A Review on Powder Bed Fusion Technology of Metal Additive Manufacturing; Chapter 16: Additive Manufacturing of Titanium Alloys; Chapter 17: Ultrasonic Additive Manufacturing; Chapter 18: Printing Components for Reciprocating Engine Applications; Chapter 19: Developing Practical Additive Manufacturing Design Methods; Chapter 20: Optical Diagnostics for Real-Time Monitoring and Feedback Control of Metal Additive Manufacturing Processes; Chapter 21: 3D Printed Structures for Nano-Scale Research; Chapter 22: Additive Manufacturing at the Micron Scale; Chapter 23: Computer Modeling of Sol-Gel Thin Film Deposition Using Finite Element Analysis; Chapter 24: Additive Manufacturing Technology Review: From Prototyping To Production; Chapter 25: Mechanical Property Optimization of Fused Deposition Modeled Polylactic Acid Components via Design of Experiments; Chapter 26: Laser powder bed fusion additive manufacturing of metals; physics, computational, and materials challenges; Chapter 27: Calculation of laser absorption by metal powders in additive manufacturing; Chapter 28: The Accuracy and Surface Roughness of Spur Gears Processed by FDM Additive Manufacturing; Chapter 29: Surface Roughness of Electron Beam Melting Ti-6Al-4v Effect on Ultrasonic Testing; Chapter 30: Dynamic Failure Properties of Additively Manufactured Stainless Steel; Chapter 31: Fatigue Life of Selective Laser Melted and Hot Isostatically Pressed Ti-6Al-4v Absent of Surface Machining; Chapter 32: Development and Implementation of Metals Additive Manufacturing; Chapter 33: Laser powder-bed fusion additive manufacturing: physics of complex melt flow and formation mechanisms of pores, spatter, and denudation zones; Chapter 34: Measurement Science Needs for Real-time Control of Additive Manufacturing Powder Bed Fusion Processes; Chapter 35: Denudation of metal powder layers in laser powder bed fusion processes; Chapter 36: Tension-compression fatigue of an oxide/oxide ceramic composite at elevated temperature; Chapter 37: Effects of steam environment on fatigue behavior of two SiC/[SiC+Si3N4] ceramic composites at 1300°C; Section III: Application Section; Chapter 38: 3D Product Design, Evaluation, Justification, and Integration; Chapter 39: 3D Printing Rises to the Occasion: ORNL group shows how it’s done, one layer at a time; Chapter 40: 3D Printing Implications for STEM education; Chapter 41: Additive Manufacturing Applicability for United States Air Force Civil Engineer Contingency Operations; Chapter 42: Additive Manufacturing Applications for Explosive Ordnance Disposal (EOD) Using the Systems Engineering Spiral Process Model; Chapter 43: Proof-of-Concept Applications of Additive Manufacturing in Air Force Explosive Ordnance Disposal Training and Operations; Chapter 44: Wing Design Utilizing Topology Optimization and Additive Manufacturing; Chapter 45: Topology Optimization of a Penetrating Warhead; Chapter 46: Iteration Revolution: DMLS Production Applications; Chapter 47: Information Storage on Additive Manufactured Parts; Index
