Principles of laser materials processing
著者
書誌事項
Principles of laser materials processing
Wiley, c2009
- : hard
大学図書館所蔵 全9件
  青森
  岩手
  宮城
  秋田
  山形
  福島
  茨城
  栃木
  群馬
  埼玉
  千葉
  東京
  神奈川
  新潟
  富山
  石川
  福井
  山梨
  長野
  岐阜
  静岡
  愛知
  三重
  滋賀
  京都
  大阪
  兵庫
  奈良
  和歌山
  鳥取
  島根
  岡山
  広島
  山口
  徳島
  香川
  愛媛
  高知
  福岡
  佐賀
  長崎
  熊本
  大分
  宮崎
  鹿児島
  沖縄
  韓国
  中国
  タイ
  イギリス
  ドイツ
  スイス
  フランス
  ベルギー
  オランダ
  スウェーデン
  ノルウェー
  アメリカ
注記
Includes bibliographical references and index
内容説明・目次
内容説明
Coverage of the most recent advancements and applications in laser materials processing This book provides state-of-the-art coverage of the field of laser materials processing, from fundamentals to applications to the latest research topics. The content is divided into three succinct parts: Principles of laser engineering-an introduction to the basic concepts and characteristics of lasers, design of their components, and beam delivery Engineering background&-a review of engineering concepts needed to analyze different processes: thermal analysis and fluid flow; solidification of molten metal; and residual stresses that evolve during processes Laser materials processing-a rigorous and detailed treatment of laser materials processing and its principle applications, including laser cutting and drilling, welding, surface modification, laser forming, and rapid prototyping Each chapter includes an outline, summary, and example sets to help readers reinforce their understanding of the material.
This book is designed to prepare graduate students who will be entering industry; researchers interested in initiating a research program; and practicing engineers who need to stay abreast of the latest developments in this rapidly evolving field.
目次
SECTION I: PRINCIPLES OF INDUSTRIAL LASERS. Chapter 1: Laser Generation. 1.1 Basic Atomic Structure. 1.2 Atomic Transitions. 1.3 Lifetime. 1.4 Optical Absorption. 1.5 Population Inversion. 1.6 Threshold Gain. 1.7 Two-Photon Absorption. 1.8 Summary. Problems. Chapter 2: Optical Resonators. 2.1 Standing Waves in a Rectangular Cavity. 2.2 Planar Resonators. 2.3 Confocal Resonators. 2.4 Generalized Spherical Resonators. 2.5 Concentric Resonators. 2.6 Stability of Optical Resonators. 2.7 Summary. Problems. Chapter 3: Laser Pumping. 3.1 Optical Pumping. 3.2 Electrical Pumping. 3.3 Summary. Problems. Chapter 4: Rate Equations. 4.1 Two-Level System. 4.2 Three-Level System. 4.3 Four-Level System. 4.4 Summary. Problems. Chapter 5: Broadening Mechanisms. 5.1 Line-Shape Function. 5.2 Line-Broadening Mechanisms. 5.3 Comparison of Individual Mechanisms. 5.4 Summary. Problems. Chapter 6: Beam Modification. 6.1 Quality Factor. 6.2 Q-Switching. 6.3 Q-Switching Theory. 6.4 Mode-Locking. 6.5 Laser Spiking. 6.6 Lamb Dip. 6.7 Summary. Problems. Chapter 7: Beam Characteristics. 7.1 Beam Divergence. 7.2 Monochromaticity. 7.3 Beam Coherence. 7.4 Intensity and Brightness. 7.5 Frequency Stabilization. 7.6 Beam Size. 7.7 Focusing. 7.8 Radiation Pressure. 7.9 Summary. Problems. Chapter 8: Types of Lasers. 8.1 Solid State Lasers. 8.2 Gas Lasers. 8.3 Dye Lasers. 8.4 Semiconductor (Diode) Lasers. 8.5 Free Electron Laser. 8.6 New Developments in Industrial Laser Technology. 8.7 Summary. Problems. Chapter 9: Beam Delivery. 9.1 The Electromagnetic Spectrum. 9.2 Reflection and Refraction. 9.3 Birefringence. 9.4 Brewster Angle. 9.5 Polarization. 9.6 Mirrors and Lenses. 9.7 Beam Expanders. 9.8 Beam Splitters. 9.9 Beam Delivery Systems. 9.10 Summary. Problems. SECTION II: ENGINEERING BACKGROUND. Chapter 10: Heat and Fluid Flow During Laser Processing. 10.1 Energy Balance During Processing. 10.2 Heat Flow in the Workpiece. 10.3 Fluid Flow in Molten Pool. 10.4 Summary. Problems. Chapter 11: The Microstructure. 11.1 Process Microstructure. 11.2 Discontinuities. 11.3 Summary. Problems. Chapter 12: Solidification. 12.1 Solidification Without Flow. 12.2 Solidification With Flow. 12.3 Rapid Solidification. 12.4 Summary. Problems. Chapter 13: Residual Stresses and Distortion. 13.1 Causes of Residual Stresses. 13.2 Basic Stress Analysis. 13.3 Effects of Residual Stresses. 13.4 Measurement of Residual Stresses. 13.5 Relief of Residual Stresses and Distortion. 13.6 Summary. Problems. SECTION III: LASER MATERIALS PROCESSING. Chapter 14: Background on Laser Processing. 14.1 System-Related Parameters. 14.2 Process Efficiency. 14.3 Disturbances that Affect Process Quality. 14.4 General Advantages and Disadvantages of Laser Processing. 14.5 Summary. Problems. Chapter 15: Laser Cutting and Drilling. 15.1 Laser Cutting. 15.2 Laser Drilling. 15.3 New Developments. 15.4 Summary. Problems. Chapter 16: Laser Welding. 16.1 Laser Welding Parameters. 16.2 Welding Efficiency. 16.3 Mechanism of Laser Welding. 16.4 Material Considerations. 16.5 Weldment Discontinuities. 16.6 Advantages and Disadvantages of Laser Welding. 16.7 Special Techniques. 16.8 Specific Applications. 16.9 Summary. Problems. Chapter 17: Laser Surface Modification. 17.1 Laser Surface Heat Treatment. 17.2 Laser Surface Melting. 17.3 Laser Direct Metal Deposition. 17.4 Laser Physical Vapor Deposition. 17.5 Laser Shock Peening. 17.6 Summary. Problems. Chapter 18: Laser Forming. 18.1 Principle of Laser Forming. 18.2 Process Parameters. 18.3 Laser Forming Mechanisms. 18.4 Process Analysis. 18.5 Advantages and Disadvantages. 18.6 Applications. 18.7 Summary. Problems. Chapter 19: Rapid Prototyping. 19.1 Computer-Aided Design. 19.2 Part Building. 19.3 Post-Processing. 19.4 Applications. 19.5 Summary. Problems. Chapter 20: Lasers in Medical and Nano Manufacturing. 20.1 Medical Applications. 20.2 Nanotechnology Applications. 20.3 Summary. Chapter 21: Sensors for Process Monitoring. 21.1 Laser Beam Monitoring. 21.2 Process Monitoring. 21.3 Summary. Problems. Chapter 22: Processing of Sensor Outputs. 22.1 Signal Transformation. 22.2 Data Reduction. 22.3 Pattern Classification. 22.4 Summary. Problems. Chapter 23: Laser Safety. 23.1 Laser Hazards. 23.2 Laser Classification. 23.3 Preventing Laser Accidents. 23.4 Summary.
「Nielsen BookData」 より