Publisher's Note: Products purchased from Third Party sellers are not guaranteed by the publisher for quality, authenticity, or access to any online entitlements included with the product. Cutting-edge coverage of the new processes, materials, and technologies that are revolutionizing the manufacturing industry Expertly edited by a past president of the Society of Manufacturing Engineers, this state-of-the-art resource picks up where the bestselling Design for Manufacturability Handbook left off. Within its pages, readers will find detailed, clearly written coverage of the technologies, and…mehr
Publisher's Note: Products purchased from Third Party sellers are not guaranteed by the publisher for quality, authenticity, or access to any online entitlements included with the product. Cutting-edge coverage of the new processes, materials, and technologies that are revolutionizing the manufacturing industry Expertly edited by a past president of the Society of Manufacturing Engineers, this state-of-the-art resource picks up where the bestselling Design for Manufacturability Handbook left off. Within its pages, readers will find detailed, clearly written coverage of the technologies, and processes that have been developed and adopted in the manufacturing industry over the past sixteen years. More than this, the book also includes hard-to-find technical guidance and application information that can be used on the job to actually apply these cutting-edge processes and technologies in a real-world setting. Essential for manufacturing engineers and designers, Design for Advanced Manufacturing is enhanced by a host of international contributors, making the book a true global resource. . Information on the latest technologies and processes such as 3-D printing, nanotechnology, laser cutting, prototyping, additive manufacturing, and CAD/CAM software toolsHinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
LaRoux Gillespie is past president of the Society of Manufacturing Engineers. Before retiring with forty years in the industry, he was Manager of Quality Assurance for the 2,800-person Division of Honeywell. Mr. Gillespie has edited or written thirty-three books and has B.S. and M.S. degrees in Mechanical Engineering, and is a Certified Manufacturing Engineer.
Inhaltsangabe
Introduction Part 1 Manufacturing with Lasers 1.1 Overview of Laser Manufacturing Processes Reference 1.2 Laser Cutting Materials Equipment Capabilities Design Considerations 1.3 Laser Surface Texturing Process Physics Why Use Laser Texturing? Design Considerations Material Suitability Laser versus Electron Beam Continuous versus Pulsed Operation Surface Topography Polishing Limitations Structuring Limitations Cost References 1.4 Laser Ablation for Cleaning, Decoating, and Surface Preparation Basic Science of Laser Ablation Surface Preparation in Manufacturing Implementation Considerations Applications Where Laser Ablation Works Best Applications Where Laser Ablation May or May Not Bring Important Benefits Manual versus Robotic Laser Ablation Precautions and Safety 1.5 Laser Hardening Process Applicable Lasers Laser Hardening Materials Grain Size Hardening Process Comparisons Application Examples Laser Hardening of Dies and Tooling Laser Hardening of Gears Laser Hardening of Machine Parts Laser Hardening of Cast Iron References 1.6 Laser Welding of Metals Applications Equipment Materials Design Considerations References 1.7 Laser Welding of Plastics Contour Welding Simultaneous Quasi-Simultaneous Mask Line Unique Variations Applications Materials Selection Joint Design Design Considerations References 1.8 Designing for Laser Soldering The Process Typical Characteristics and Applications Economics Suitable Materials Design Recommendations Through-Hole Pad Design Lap Joint Pad Design Connector Selection Fixturing Lead-to-Hole Ratio 1.9 Design for Laser Cladding The Laser Cladding Process Laser Cladding and Conventional Welding Laser Cladding with Powder versus Wire Laser Cladding with Powder Laser Cladding with Wire Applications and Cladding Variables Filler Materials Laser Cladding Production Performance 1.10 Laser Marking and Engraving Laser Marking Materials That Can Be Marked Selecting a Laser Marking Metals Anneal Marking Engraving and Etching Plastic, Glass, Coated, and Paper Marking Marking on Painted Surfaces 1.11 Laser-Assisted Forming Laser Forming Laser-Assisted Forming Laser-Assisted Micro Forming References 1.12 Laser Peening Laser Peening Process Typical Characteristics and Applications Residual Stress Magnitude and Depth Residual Stress Stability Surface Roughness Effects Material Properties Compensating Stresses and Deformation Common Applications Economics General Process Design Considerations Design Methodology Pattern Size and Location Intensity and Coverage Suitable Materials Detailed Design Considerations Variations Based on Supplier Intensity and Coverage Specification Patch Size and Location on Drawings Processing of Thin Sections and Shot Orders Minimum Thickness Part 2 Manufacturing with Additive Processes 2.1 Overview of Additive Manufacturing Processes Overview of Primary Additive Manufacturing Technologies General Design Considerations for Additive Manufacturing References 2.2 Binder Jetting The Process and Materials Typical Characteristics and Applications As Bonded Lightly Sintered Sintered and Infiltrated Highly Sintered Advantages of Binder Jetting Economics General Design Considerations Suitable Materials Detailed Design Considerations Wall Thickness Uniform Wall Thickness Inside Edges Interior Holes Part Connections 2.3 Directed Energy Deposition Metals Applications Design Issues References 2.4 Material Extrusion Applications Considerati
Introduction Part 1 Manufacturing with Lasers 1.1 Overview of Laser Manufacturing Processes Reference 1.2 Laser Cutting Materials Equipment Capabilities Design Considerations 1.3 Laser Surface Texturing Process Physics Why Use Laser Texturing? Design Considerations Material Suitability Laser versus Electron Beam Continuous versus Pulsed Operation Surface Topography Polishing Limitations Structuring Limitations Cost References 1.4 Laser Ablation for Cleaning, Decoating, and Surface Preparation Basic Science of Laser Ablation Surface Preparation in Manufacturing Implementation Considerations Applications Where Laser Ablation Works Best Applications Where Laser Ablation May or May Not Bring Important Benefits Manual versus Robotic Laser Ablation Precautions and Safety 1.5 Laser Hardening Process Applicable Lasers Laser Hardening Materials Grain Size Hardening Process Comparisons Application Examples Laser Hardening of Dies and Tooling Laser Hardening of Gears Laser Hardening of Machine Parts Laser Hardening of Cast Iron References 1.6 Laser Welding of Metals Applications Equipment Materials Design Considerations References 1.7 Laser Welding of Plastics Contour Welding Simultaneous Quasi-Simultaneous Mask Line Unique Variations Applications Materials Selection Joint Design Design Considerations References 1.8 Designing for Laser Soldering The Process Typical Characteristics and Applications Economics Suitable Materials Design Recommendations Through-Hole Pad Design Lap Joint Pad Design Connector Selection Fixturing Lead-to-Hole Ratio 1.9 Design for Laser Cladding The Laser Cladding Process Laser Cladding and Conventional Welding Laser Cladding with Powder versus Wire Laser Cladding with Powder Laser Cladding with Wire Applications and Cladding Variables Filler Materials Laser Cladding Production Performance 1.10 Laser Marking and Engraving Laser Marking Materials That Can Be Marked Selecting a Laser Marking Metals Anneal Marking Engraving and Etching Plastic, Glass, Coated, and Paper Marking Marking on Painted Surfaces 1.11 Laser-Assisted Forming Laser Forming Laser-Assisted Forming Laser-Assisted Micro Forming References 1.12 Laser Peening Laser Peening Process Typical Characteristics and Applications Residual Stress Magnitude and Depth Residual Stress Stability Surface Roughness Effects Material Properties Compensating Stresses and Deformation Common Applications Economics General Process Design Considerations Design Methodology Pattern Size and Location Intensity and Coverage Suitable Materials Detailed Design Considerations Variations Based on Supplier Intensity and Coverage Specification Patch Size and Location on Drawings Processing of Thin Sections and Shot Orders Minimum Thickness Part 2 Manufacturing with Additive Processes 2.1 Overview of Additive Manufacturing Processes Overview of Primary Additive Manufacturing Technologies General Design Considerations for Additive Manufacturing References 2.2 Binder Jetting The Process and Materials Typical Characteristics and Applications As Bonded Lightly Sintered Sintered and Infiltrated Highly Sintered Advantages of Binder Jetting Economics General Design Considerations Suitable Materials Detailed Design Considerations Wall Thickness Uniform Wall Thickness Inside Edges Interior Holes Part Connections 2.3 Directed Energy Deposition Metals Applications Design Issues References 2.4 Material Extrusion Applications Considerati
Es gelten unsere Allgemeinen Geschäftsbedingungen: www.buecher.de/agb
Impressum
www.buecher.de ist ein Internetauftritt der buecher.de internetstores GmbH
Geschäftsführung: Monica Sawhney | Roland Kölbl | Günter Hilger
Sitz der Gesellschaft: Batheyer Straße 115 - 117, 58099 Hagen
Postanschrift: Bürgermeister-Wegele-Str. 12, 86167 Augsburg
Amtsgericht Hagen HRB 13257
Steuernummer: 321/5800/1497
USt-IdNr: DE450055826
