Precision additive metal manufacturing 1st edition by Richard Leach, Simone Carmignato ISBN 113834771X ‎ 978-1138347717 by Leach, R K(contributor);carmignato, Simone(contributor) 9780429436543, 9780429791260, 9780429791277, 9780429791284, 9781138347717, 0429436548, 0429791267, 0429791275, 0429791283 instant download after payment.

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ISBN 10: 113834771X
ISBN 13: ‎ 978-1138347717
Author: Richard Leach, Simone Carmignato 

Additive manufacturing (AM) is a fast-growing sector with the ability to evoke a revolution in manufacturing due to its almost unlimited design freedom and its capability to produce personalised parts locally and with efficient material use. AM companies, however, still face technological challenges such as limited precision due to shrinkage, built-in stresses and limited process stability and robustness. Moreover, often post-processing is needed due to high roughness and remaining porosity. Qualified, trained personnel are also in short supply.

Precision additive metal manufacturing 1st Table of contents:

Chapter 1 Introduction to Precision Metal Additive Manufacturing

1.1 Introduction to Additive Manufacturing

1.2 Basic Definitions

1.2.1 General Terms

1.2.2 Process Categories

1.2.3 Other Terms

1.3 Towards Precision Additive Manufacturing

References

Chapter 2 Topology Optimisation Techniques

2.1 Introduction

2.2 Topology Optimisation

2.2.1 Density-Based TO Method

2.2.1.1 Problem Formulation

2.2.1.2 Sensitivity Analysis

2.2.1.3 Filtering Techniques

2.2.1.4 Solution Approaches

2.2.1.5 Application Domains

2.3 Topology Optimisation for Precision Metal AM

2.3.1 TO Methods for Avoiding Overhangs in Precision AM Parts

2.3.1.1 Two-Dimensional Overhang Control

2.3.1.2 3D Overhang Control

2.3.1.3 Support Inclusion

2.3.2 TO Methods for Preventing Overheating in Precision AM Parts

2.3.3 Towards TO Methods for Avoiding Distortion in Precision AM Parts

2.4 Challenges and Outlook

References

Chapter 3 Development of Precision Additive Manufacturing Processes

3.1 Introduction

3.2 State of the Art and Insight into Precision Process Development

3.3 Setting Priorities

3.4 Significant Process Parameters

3.4.1 Laser-Related Process Parameters

3.4.2 Scan-Related Process Parameters

3.4.3 Powder-Related Process Parameters

3.4.4 Build Chamber-Related Parameters

3.4.5 Combined Processing Parameters

3.5 Additive Manufacturing Performance Indicators

3.5.1 Mechanical Properties

3.5.2 Dimensional Accuracy

3.5.3 Surface Texture

3.5.4 Part Density

3.5.5 Total Build Time

3.5.6 Energy Consumption

3.5.7 System-Wide Performance Indicators

3.6 Data-Driven Process Improvement

3.6.1 Design of Experiments

3.6.2 Modelling of Process Performance (Quantifying Input/Output Process Relationships)

3.6.2.1 Regression and Statistical Analysis

3.6.2.2 Artificial Neural Network Modelling

3.6.3 Process Optimisation

3.7 Precision Processes in the Domain of Industry 4.0

3.7.1 Real-Time Monitoring of AM Processes

3.7.2 Artificial Intelligence and Decision-Making Systems for Digital Quality Control

3.8 Future Perspectives for Precision AM Processes

3.9 Conclusions

Acknowledgements

References

Chapter 4 Modelling Techniques to Enhance Precision in Metal Additive Manufacturing

4.1 Introduction

4.2 Demystifying AM through Simulations

4.2.1 The Physics of Laser Powder Bed Fusion

4.2.2 Challenges of Length and Time Scales

4.3 Warpage and Distortion Predictions by Macro-Scale Modelling of AM

4.3.1 Understanding Thermal History, Residual Stresses and Distortions

4.3.2 Goals and Challenges in Macro-Scale Modelling of AM Parts

4.3.3 Full-Scale, Reduced-Order and Effective Models

4.4 Tracking Powders, Pores and Melt Pools during AM through Meso-Scale Models

4.4.1 Powder Bed Formation and Representation

4.4.2 Simulating Laser–Material Interactions

4.4.3 Melt-Pool Dynamics in a Powder Bed

4.4.4 Evolution of Porosity during AM

4.4.5 Surfaces and Solidification during AM

4.5 Microstructure Simulations in Precision AM

4.5.1 Understanding the Metallurgical Needs

4.5.2 Metallurgical Modelling Techniques

4.5.3 Revisiting Solidification during AM from a Metallurgical Perspective

4.5.4 Need for Heat-Treatment as Post-Process

4.6 Data-Driven Modelling for Process Windows

4.6.1 Data-Based Models

4.6.2 Digital and Physical Design of Experiments

4.6.3 GIGO Approach to Model Calibration

4.7 Concluding Remarks and Future Outlook

References

Chapter 5 Secondary Finishing Operations

5.1 Introduction

5.2 Basic Definition of Secondary Finishing

5.2.1 What Is Considered to Be Secondary Finishing in This Chapter?

5.2.2 Not Included in the Scope of This Chapter

5.3 Why Do AM Surfaces Need to Be Finished?

5.3.1 Impact of Surface Topography on Function

5.3.1.1 Fatigue Applications

5.3.2 Examples of AM Surfaces

5.4 Specification Standards in Secondary Finishing

5.5 Challenges for Finishing Operations for AM Parts

5.5.1 Typical Operational Challenges for Metal AM Components Due to Surface Morphologies and Topogra

5.5.1.1 Challenges of Surface Topography

5.5.1.2 Supporting Material and Witness Marks

5.5.1.3 Distortion

5.5.2 Geometrical Challenges for Finishing Operations

5.5.3 AM Process Chain Challenges for Finishing Operations

5.5.4 Finishing Challenges for AM in Precision Applications

5.6 Available Secondary Finishing Processes

5.6.1 Conventional Machining Methods

5.6.2 Non-Conventional Machining Methods

5.6.3 Emerging Technologies Developed for AM

5.6.3.1 Chemical Processes

5.6.3.2 Hybrid Mass Finishing and Chemical

5.6.3.3 Hybrid Mass Finishing and Electropolishing

5.6.3.4 Electropolishing Developments

5.6.3.5 Mass Finishing Targeted at AM

5.7 What Processes Are Appropriate for AM?

5.7.1 Narrow Channels

5.7.2 Complex Internal Channels

5.7.3 Internal Cavities (Surface Connected)

5.7.4 Variable Cross-Section Internal Channels

5.7.5 Outer Lattice Surfaces

5.7.6 Inner Lattice Surfaces

5.7.7 Thin Features

5.7.8 Closed Internal Cavities

5.8 Other Considerations for Finishing Operations in AM

5.9 How to Impact AM Design for Finishing

5.10 Future Work

5.10.1 New Processes and Technologies in Development

5.10.1.1 Hybrid AFM

5.10.1.2 Laser Polishing

5.10.1.3 Automation and Modelling

5.10.2 Future of This Field

5.10.2.1 Internal Targeted Finishing

5.10.2.2 Hybrid Technologies

5.10.2.3 Design Processes

5.10.2.4 Specification Standards

5.10.2.5 Automation and Targeted Finishing

References

Chapter 6 Standards in Additive Manufacturing

6.1 Introduction

6.2 AM Standards Roadmaps

6.2.1 America Makes

6.2.2 Identified Gaps in the Roadmaps

6.3 AM Powder Feedstock Characterisation Standards

6.3.1 Feedstock Sampling Strategy

6.3.2 Particle Size Determination and Distribution

6.3.3 Morphology Characterisation Methods

6.3.4 Flow Characteristics

6.3.5 Thermal Characterisation

6.3.6 Density Determination

6.3.7 Chemical Composition

6.4 Processes

6.5 Part Verification

6.5.1 Tensile Properties

6.5.2 Compressive Properties

6.5.3 Hardness Measurement

6.5.4 Fatigue Measurement Methods

6.5.5 Fracture Toughness

6.5.6 Other Properties

6.6 Surface Standards

6.6.1 Profile and Areal Surfaces

6.7 Dimensional Standards

6.7.1 Performance Verification of Coordinate Measuring Machines

6.8 Non-Destructive Evaluation Standards

6.8.1 Current Standards

6.8.2 Welding Standards

6.8.3 Casting Standards

6.9 Future and Planned Standards Activities

References

Chapter 7 Cost Implications of Precision Additive Manufacturing

7.1 Introduction

7.2 A Primer in Manufacturing Cost Modelling

7.3 Developing an AM Costing Framework

7.4 Specifying a Simple Cost Model for Precision AM

7.5 A Brief Discussion of the Cost Model for Precision AM

7.5.1 Indirect Cost Rates

7.5.2 Capacity Utilisation

7.5.3 Integration with Other Operational Processes

7.5.4 Relationship between Failure Parameters and Costs of Inspection

7.6 Summary and Additional Perspectives

References

Chapter 8 Machine Performance Evaluation

8.1 Introduction

8.1.1 Definitions

8.1.2 Motivation

8.1.3 Background

8.1.4 Organisation of This Chapter

8.2 Three-Dimensional Test Artefacts

8.2.1 Key Contributions to 3D Test Artefacts

8.2.2 Strengths and Challenges of 3D Test Artefacts

8.2.3 Considerations for 3D Test Artefact Design

8.3 Component Testing

8.3.1 Key Contributions to Component Testing

8.3.2 Strengths and Challenges of Component Testing

8.3.3 General Principles of Component Testing

8.3.4 Z-Axis

8.3.5 Directed Energy Deposition Machine Error Motions

8.3.6 Powder Bed Fusion Machine Error Motions

8.3.7 Energy Beam Diagnostics

8.3.8 Non-Geometric Measurements

8.4 Two-Dimensional Test Artefacts

8.4.1 Strengths and Challenges of 2D Test Artefacts

8.4.2 Key Contributions to 2D Test Artefacts

8.4.3 Considerations for Designing a 2D Test Artefact

8.5 Areas for Future Research

Disclaimer

References

Chapter 9 Non-Destructive Evaluation for Additive Manufacturing

9.1 Introduction

9.2 Typical Defects in AM

9.3 NDE Challenges in AM

9.4 NDE Methods – Advantages and Limitations

9.5 NDE Standardisation for AM

9.6 NDE for Qualification in AM

9.6.1 Post-Process Inspection

9.6.2 In-Process Inspection

9.7 NDE Reliability in AM

9.7.1 General Aspects of Experimental Pod Curves

9.7.1.1 General Aspects of PoD Curves Modelled through Experimental Data

9.7.1.2 Mathematical Simulation of PoD Curves

9.7.2 Estimation of Experimental PoD

9.8 Current PoD Performed in AM

9.9 Conclusions and Future Research

Acknowledgements

References

Chapter 10 Post-Process Coordinate Metrology

10.1 Introduction

10.2 Basic Definitions

10.2.1 Surface and Coordinate Metrology Terms and Definitions

10.2.2 General Metrology Terms and Definitions

10.3 Basics for Coordinate Metrology

10.3.1 Coordinate Metrology System Configurations

10.3.2 Coordinate Metrology Software

10.3.3 CMS Alignment

10.3.4 CMS Errors

10.4 Contact Methods

10.4.1 Contact Probe Types

10.4.2 Contact Probe Errors

10.4.3 AM Roughness Issues with Contact Probing

10.5 Optical Methods

10.5.1 Vision Systems

10.5.2 Scanning Optical Probes

10.5.2.1 Time-of-Flight Method

10.5.2.2 Laser Triangulation

10.5.3 Areal Optical Probes

10.5.3.1 Digital Fringe Projection Technique

10.5.3.2 Photogrammetry

10.6 Calibration and Traceability

10.6.1 Current Performance Evaluation Framework

10.6.2 Current Uncertainty Framework

10.6.3 Issues with Non-Contact CMS Performance Evaluation

10.6.4 Towards Calibration of Non-Contact CMSs

10.7 Current Research and Future Look

Acknowledgements

References

Chapter 11 Post-Process Surface Metrology

11.1 Introduction

11.1.1 The Nature of Metal AM Surfaces

11.2 Definitions and Standards

11.2.1 Surface Metrology Terms and Definitions

11.2.2 Relevant Specification Standards

11.2.2.1 Profile Standards

11.2.2.2 Areal Standards

11.2.2.3 Other Standards

11.3 Surface Topography Measurement

11.3.1 System Architectures

11.3.1.1 Profile and Areal Topography Measurement Systems

11.3.1.2 Three-Axis And Five-Axis Topography Measurement Systems

11.3.1.3 Three- and Five-Axis Measurement on AM Surfaces

11.3.2 Surface Topography Datasets

11.3.2.1 Height Maps

11.3.2.2 Triangle Meshes

11.3.3 Contact Methods

11.3.3.1 Stylus Instruments – Basics

11.3.3.2 Stylus Instruments – Uses in AM

11.3.4 Non-Contact, Optical Methods

11.3.4.1 Optical Methods for Topography Measurement – Basics

11.3.4.2 Optical Measurement of Surface Topography – Uses in AM

11.3.5 Non-Contact, Non-Optical Methods

11.3.5.1 Scanning Electron Microscopy – Basics

11.3.5.2 Scanning Electron Microscopy – Uses in AM

11.3.5.3 X-Ray Computed Tomography – Basics

11.3.5.4 X-Ray Computed Tomography – Uses in AM

11.3.6 Performance Comparison of Non-Contact Methods

11.3.7 Pseudo-Contact Methods

11.3.7.1 Scanning Probe Microscopy – Basics

11.3.7.2 Scanning Probe Microscopy – Uses in AM

11.4 Surface Topography Analysis

11.4.1 Topography Data Pre-Processing

11.4.2 Topography Data Pre-Processing for AM Surfaces

11.4.3 Surface Texture Parameters

11.4.3.1 The Arithmetical Mean Deviation of the Roughness Profile – Ra

11.4.3.2 Areal Height Parameters

11.4.3.3 Areal Height Parameters – Uses in AM

11.4.3.4 The Areal Material Ratio Curve and Related Parameters

11.4.3.5 The Areal Material Ratio Curve and Related Parameters – Uses in AM

11.4.3.6 Spatial Parameters

11.4.3.7 Spatial Parameters – Uses in AM

11.4.4 Topography Segmentation and Characterisation of Surface Features

11.4.5 Topography Segmentation and Characterisation of Surface Features – Uses in AM

11.4.6 Characterisation of Full-3D Topographies

11.5 Uncertainty in Surface Topography Measurement and Characterisation

11.6 Current Research and Future Look

References

Chapter 12 X-Ray Computed Tomography

12.1 Introduction

12.2 Fundamentals of Industrial X-Ray Computed Tomography

12.2.1 Evolution of X-Ray Computed Tomography

12.2.2 Industrial CT Systems – Configurations and Components

12.2.2.1 X-Ray Source

12.2.2.2 X-Ray Detector

12.2.2.3 Kinematic System

12.2.3 CT Scanning Process

12.3 Measurement Errors and Traceability

12.3.1 Main Error Sources and CT Image Artefacts

12.3.2 Metrological Performance Verification

12.3.3 Uncertainty Determination

12.3.4 Reference Objects

12.4 Applications of CT Metrology for AM

12.4.1 Dimensional and Geometrical Product Verification

12.4.2 Internal Defect Analysis

12.4.3 Surface Topography Characterisation

12.4.4 Powder Feedstock Characterisation

12.4.5 Product Development and Process Optimisation

12.4.5.1 CT for Product Development

12.4.5.2 CT for Process Optimisation

12.5 Conclusion and Future Look

References

Chapter 13 On-Machine Measurement, Monitoring and Control

13.1 Introduction

13.2 Basic Definitions and Terminology

13.3 Defects and Their Fingerprint in PBF Processes

13.3.1 Causes of Defects

13.3.1.1 Defects Induced by Feedstock Material

13.3.1.2 Equipment-Induced Defects

13.3.1.3 Defects due to Improper Design or Job Preparation

13.3.1.4 Process Setting–Induced Defects

13.3.2 Types of Defects

13.3.2.1 Porosity

13.3.2.2 Residual Stresses, Cracks and Delamination

13.3.2.3 Microstructural Inhomogeneity and Impurities

13.3.2.4 Balling

13.3.2.5 Dimensional and Geometrical Deviations

13.3.2.6 Surface Defects

13.4 On-Machine Sensing Methods and Architectures

13.4.1 Basic Principles

13.4.1.1 Electromagnetic Spectral Ranges for On-Machine Measurements

13.4.1.2 Spatially Integrated Sensors

13.4.1.3 Spatially Resolved Sensors

13.4.2 Data Gathering Levels

13.4.3 On-Machine Sensing Architectures

13.4.3.1 Co-Axial Sensing

13.4.3.2 Off-Axis Sensing

13.4.4 Mapping between On-Machine Sensing, Process Signatures and Process Defects

13.5 On-Machine Measurement

13.5.1 On-Machine Topography Reconstruction

13.5.2 Other Methods

13.6 Statistical Process Monitoring Using On-Machine Sensing

13.6.1 Basic Principles of SPM

13.6.1.1 False Alarms and False Negatives: Type I and Type II Errors

13.6.1.2 Control Charts

13.6.2 Examples of SPM

13.6.2.1 On-Machine Monitoring Example, Level 1

13.6.2.2 On-Machine Monitoring Example, Level 2

13.7 Process Control

13.7.1 Feedback Control

13.7.2 Feedforward Control

13.8 Current Research and Future Look

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