Laser-Based Remanufacturing
1st Edition
Published on 28. December 2022
Book
Hardback
300 pages
978-3-527-41261-7 (ISBN)
Description
Written by expert authors from both academia and industry with considerable experience in laser material processing, manufacturing and remanufacturing, this book covers the fundamentals, basic science and technologies involved in laser remanufacturing with applications for the repair of worn mechanical components. It introduces the advantages of laser-based remanufacturing technologies and activities as well as the relevant phenomena observed. Several laser remanufacturing techniques and their relevant processing parameters, systems, quality controls and characteristics of the remanufactured parts are discussed, as are efficiency assessment, remanufactured product cycling, technical design and management.
Based on the authors' research and practice over the last three decades but also incorporating results and examples from other researchers and organizations worldwide, this useful guide includes real-life case studies and numerous examples of applications in various industrial fields, such as transportation vehicles, steel and iron production, energy industries, engineering mechanism, and chemical industries.
Based on the authors' research and practice over the last three decades but also incorporating results and examples from other researchers and organizations worldwide, this useful guide includes real-life case studies and numerous examples of applications in various industrial fields, such as transportation vehicles, steel and iron production, energy industries, engineering mechanism, and chemical industries.
More details
Language
German
Place of publication
Weinheim
Germany
Target group
Professional and scholarly
Dimensions
Height: 244 mm
Width: 170 mm
ISBN-13
978-3-527-41261-7 (9783527412617)
Copyright in bibliographic data is held by Nielsen Book Services Limited or its licensors: all rights reserved.
Schweitzer Classification
Persons
Professor Shiyun Dong works at the National Key Laboratory for Remanufacturing in Beijing, China. HE received his Ph.D in materials science from Harbin Institute of Technology, Harbin, China, in 2000. His early research was on laser cladding and surface engineering technology. Professor Dong has authored and co-authored over 100 scientific publications and has received several scientific prizes and granted patents.
Professor Lin Li holds a chair of laser engineering and has been the Director of the Laser Processing Research Centre at The University of Manchester, UK since 2000. He is the author and co-author of over 300 journal publications in laser processing including additive manufacturing, laser cladding, welding and surface engineering and inventor and co-inventor of 47 patents in laser processing. He is a member of the board of directors, a fellow of the Laser Institute of America, a member of the executive committee of the Association of Laser Users, a fellow of the International Academy of Production Engineering, CIRP and a fellow of the Institute of Engineering and Technology. He is also a member of several Editorial Boards in 12 international journals.
Professor Binshi Xu is a Fellow of the National Academy of Engineering, China and the founding director of the National Key Laboratory for Remanufacturing, China. He is internationallyrecognized for his pioneering research and applications in remanufacturing, welding and surface engineering. He has authored over 200 scientific publications and has received numerous scientific prizes and granted patents.
Professor Lin Li holds a chair of laser engineering and has been the Director of the Laser Processing Research Centre at The University of Manchester, UK since 2000. He is the author and co-author of over 300 journal publications in laser processing including additive manufacturing, laser cladding, welding and surface engineering and inventor and co-inventor of 47 patents in laser processing. He is a member of the board of directors, a fellow of the Laser Institute of America, a member of the executive committee of the Association of Laser Users, a fellow of the International Academy of Production Engineering, CIRP and a fellow of the Institute of Engineering and Technology. He is also a member of several Editorial Boards in 12 international journals.
Professor Binshi Xu is a Fellow of the National Academy of Engineering, China and the founding director of the National Key Laboratory for Remanufacturing, China. He is internationallyrecognized for his pioneering research and applications in remanufacturing, welding and surface engineering. He has authored over 200 scientific publications and has received numerous scientific prizes and granted patents.
Content
1 Introduction
1.1 Definition of remanufacturing
1.2 The society need for remanufacturing
1.3 History of remanufacturing
1.4 Basic remanufacturing science technologies
1.5 Applications of remanufacturing
1.6 Trends of remanufacturing
2 Background of laser based remanufacturing, LBR
2.1 Laser materials processing
2.2 Functions of laser based remanufacturing
2.3 Classification of laser based remanufacturing technology
2.4 An overview of the historical developments of LBR
3 Fundamentals of laser based remanufacturing
3.1 Basic knowledge of lasers used in LBR
3.2 Phenomena of laser beam interaction with metals
3.3 Laser heating metals
3.4 Physical metallurgy of LBR
3.5 Material systems for LBR
4 LBR with laser additive layer manufacturing technology
4.1 Laser additive layer manufacturing introduction
4.2 Temperature fields during laser metal deposition
4.3 Residual stress in LBR metal parts
4.4 Microstructure characteristics of laser deposited materials
4.5 Property advantages of laser deposition
4.6 Modelling of laser additive layer manufacturing process
4.7 Stereo-solid remanufacturing by lasers
4.8 Applications of laser additive layer manufacturing for LBR
5 Laser welding for remanufacturing
5.1 Introduction of laser welding techniques
5.2 Methods and mechanisms of laser welding
5.3 Process of laser welding for LBR
5.4 Applications examples for LBR
6 Laser cutting for remanufacturing
6.1 Introduction on laser cutting
6.2 Theory of laser cutting
6.3 Process of laser cutting
6.4 Applications of laser cutting for LBR
7 Laser cleaning for remanufacturing
7.1 Introduction of laser cleaning
7.2 Mechanisms of laser cleaning
7.3 Process of laser cleaning
7.3 Applications of laser cleaning for LBR
8 Efficiency assessment of LBR
8.1 Environmental benefits
8.2 Social benefits
8.3 Economic benefits
9 Non-destructive testing and evaluation for laser remanufactured products
9.1 Introduction on NDT methods
9.2 Defects and their detections
9.3 Residual stress
9.4 Evaluation on performance of laser remanufactured products
10 Systems engineering and management in LBR
10.1 Sustainable cycling of products and components
10.2 Industrial activities on LBR
10.3 Product cycling and management for LBR
10.4 Technical standards on LBR
11 Applications and examples
11.1 Purposes and rules of LBR applications
11.2 Engineering design of laser remanufacturing processes
11.3 Application examples
- Transportation vehicles
- Steel and iron production
- Energy industries
- Engineering mechanism
- Chemical industries
11.4 Future prospects
12 Laser safety in LBR
12.1 Laser classification
12.2 Safety rules and regulations
12.3 The safety limits
12.4 Damage to human body from typical Class 4 laser
12.5 Risks from LBR
12.6 The laser hazards and dangers
12.7. Safety measures in LBR
1.1 Definition of remanufacturing
1.2 The society need for remanufacturing
1.3 History of remanufacturing
1.4 Basic remanufacturing science technologies
1.5 Applications of remanufacturing
1.6 Trends of remanufacturing
2 Background of laser based remanufacturing, LBR
2.1 Laser materials processing
2.2 Functions of laser based remanufacturing
2.3 Classification of laser based remanufacturing technology
2.4 An overview of the historical developments of LBR
3 Fundamentals of laser based remanufacturing
3.1 Basic knowledge of lasers used in LBR
3.2 Phenomena of laser beam interaction with metals
3.3 Laser heating metals
3.4 Physical metallurgy of LBR
3.5 Material systems for LBR
4 LBR with laser additive layer manufacturing technology
4.1 Laser additive layer manufacturing introduction
4.2 Temperature fields during laser metal deposition
4.3 Residual stress in LBR metal parts
4.4 Microstructure characteristics of laser deposited materials
4.5 Property advantages of laser deposition
4.6 Modelling of laser additive layer manufacturing process
4.7 Stereo-solid remanufacturing by lasers
4.8 Applications of laser additive layer manufacturing for LBR
5 Laser welding for remanufacturing
5.1 Introduction of laser welding techniques
5.2 Methods and mechanisms of laser welding
5.3 Process of laser welding for LBR
5.4 Applications examples for LBR
6 Laser cutting for remanufacturing
6.1 Introduction on laser cutting
6.2 Theory of laser cutting
6.3 Process of laser cutting
6.4 Applications of laser cutting for LBR
7 Laser cleaning for remanufacturing
7.1 Introduction of laser cleaning
7.2 Mechanisms of laser cleaning
7.3 Process of laser cleaning
7.3 Applications of laser cleaning for LBR
8 Efficiency assessment of LBR
8.1 Environmental benefits
8.2 Social benefits
8.3 Economic benefits
9 Non-destructive testing and evaluation for laser remanufactured products
9.1 Introduction on NDT methods
9.2 Defects and their detections
9.3 Residual stress
9.4 Evaluation on performance of laser remanufactured products
10 Systems engineering and management in LBR
10.1 Sustainable cycling of products and components
10.2 Industrial activities on LBR
10.3 Product cycling and management for LBR
10.4 Technical standards on LBR
11 Applications and examples
11.1 Purposes and rules of LBR applications
11.2 Engineering design of laser remanufacturing processes
11.3 Application examples
- Transportation vehicles
- Steel and iron production
- Energy industries
- Engineering mechanism
- Chemical industries
11.4 Future prospects
12 Laser safety in LBR
12.1 Laser classification
12.2 Safety rules and regulations
12.3 The safety limits
12.4 Damage to human body from typical Class 4 laser
12.5 Risks from LBR
12.6 The laser hazards and dangers
12.7. Safety measures in LBR