注册并扫描二维码
免费送会刊
科技前沿

复合材料英文经典著作(二十五)《天然纤维增强复合材料— —材料、工艺和性能》
来源:武汉理工王继辉教授课题组  2017-06-09 09:47:14
本文阅读次数:126

原文:http://chinacompositesexpo.com/cn/news.php?show=detail&c_id=288&news_id=4934作者:Alma Hodzic,Robert Shanks
出版社:Woodhead Publishing,2014


 
       近年来,以天然纤维作为复合材料增强材料的应用的重要性日趋显著。《天然纤维增强复合材料》一书总结了近期这一领域内的重要研究成果。
       本书第一部分中各章介绍和探讨了天然纤维增强材料的结构、性能、制备和应用,涵盖由木质纤维和纤维素纤维制成的增强材料。第二部分阐述了天然纤维增强复合材料的制备,各章讨论了绿色复合材料制备工艺的伦理学准则,天然纤维增强复合材料的制造方法、模压和注塑技术,以及天然纤维增强热固性复合材料。第三部分着重介绍天然纤维增强复合材料的测试和性能,包括无损检测和高应变率测试。对天然纤维增强复合材料进行了动态载荷下的性能检测,评估了其对冲击损伤的响应,还评估了其在海洋环境中的响应。
       《天然纤维增强复合材料》一书可为需要了解天然纤维增强复合材料的专业人士提供技术指导,同时也可为科研人员和工程人员提供相关领域的评述、应用和评估指导。
  • 介绍和探索天然纤维增强增强材料的结构、性能、制备和应用,涵盖了由木材纤维和纤维素纤维制成的天然纤维增强材料。
  • 重点介绍和阐述天然纤维增强复合材料的测试和性能,包括无损检测和高应变率测试。
  • 考察天然纤维增强复合材料在动态载荷下的响应、对冲击损伤的响应,以及其应用于海洋环境中的响应。

媒体推荐
       "本书书如其名。书中涵盖了国际研究者感兴趣的广泛课题.....我惊喜地发现其中包括关于复合材料产品相关的伦理学考虑......我有其中一些旧参考书......我预期本书将会被许多科学家收藏。"—Wood and Fiber Science 46(3), 2014"《天然纤维增强复合材料》分为三部分,讨论了增强材料的应用、制备和技术性能评估。关于增强材料应用的内容包含了木质纤维的应用、纤维素纤维的化学性质、层状(木质素)纤维素结构、可回收的聚合物。"—ProtoView.com, 2014年4月

作者简介
       Alma Hodzic,英国谢菲尔德大学,先进制造研究院,先进材料技术与研究分部,教授、研究部主任。
       Robert Shanks,澳大利亚墨尔本皇家理工大学,应用科学学院,高分子材料科学系,荣誉教授。

目录

Part I: Natural fibre reinforcements

Chapter 1: Wood fibres as reinforcements in natural fibre composites: structure, properties, processing and applications
1.1 Introduction
1.2 Wood fibres: nature and behaviour
1.3 Modification of wood fibres for composites
1.4 Matrices (binders) of wood fibre composites
1.5 Process techniques of wood fibre composites1.6 Properties of wood fibre composites
1.7 Applications of wood fibre composites
1.8 Future trends

Chapter 2: Chemistry and structure of cellulosic fibres as reinforcements in natural fibre composite2.1 Introduction
2.2 Glucose monomer
2.3 Glucose biopolymerization
2.4 Cellulose structure
2.5 Chemical and solubility properties of cellulose2.6 Sources of cellulose
2.7 Separation of cellulose
2.8 Purification of cellulose
2.9 Cellulose polymorphism
2.10 Chemical modification of cellulose
2.11 Preparation of nano-cellulose
2.12 Processing of cellulose
2.13 Applications of cellulose fibres
2.14 Conclusions
2.15 Appendix: abbreviations

Chapter 3: Creating hierarchical structures in cellulosic fibre reinforced polymer composites for advanced performance
3.1 Introduction
3.2 Creating hierarchical structures in cellulosic fibre reinforced composite materials
3.3 Surface microfibrillation of (ligno)cellulosic fibres
3.4 Creating hierarchical structures in renewable composites by incorporating microfibrillated cellulose (MFC) into the matrix
3.5 Coating of (ligno)cellulosic fibres with bacterial cellulose
3.6 Conclusions and future trends
3.7 Acknowledgements

Chapter 4: Recycled polymers in natural fibre-reinforced polymer composites
4.1 Introduction
4.2 Fibre reinforcements in recycled composites
4.3 Processes for adding natural fibre reinforcements to composites
4.4 Improving the mechanical properties of recycled composites using natural fibre reinforcements
4.5 Applications of recycled polymer composites with natural fibre reinforcements
4.6 Conclusions and future trends
4.7Appendix: abbreviations

Chapter 5: Electrospun cellulosic fibre-reinforced composite materials
5.1 Introduction
5.2 Electrospinning of non-derivatised and derivatised cellulosic fibres
5.3 Electrospun cellulosic fibres via polymer blends
5.4 Electrospun nanocomposite fibres
5.5 Mechanical properties of electrospun fibres and mats
5.6 Cellulose nanofibre-reinforced polymer composites
5.7 Future trends

Part II: Processing of natural fibre composites

Chapter 6: Ethical practices in the processing of green composites
6.1 Introduction
6.2 Social impact and ethical practice
6.3 Case study:Waste for Life waste management model
6.4 Conclusions

Chapter 7: Manufacturing methods for natural fibre composites
7.1 Introduction
7.2 Fibre reinforcements
7.3 Reinforcement forms
7.4 Bio-based polymer matrices
7.5 Composites manufacturing processes
7.6 Key parameters for successful processing of natural fibre composites
7.7 Manufacturing techniques for natural fibre- reinforced polymer matrix composites
7.8 Case studies: automotive, building and construction, and marine applications
7.9 Conclusions

Chapter 8: Compression and injection molding techniques for natural fiber composites
8.1 Introduction
8.2 Emerging compression and injection molding technologies in the production of natural fiber composites
8.3 Processing natural fiber composites at high temperatures
8.4 Conclusions

Chapter 9: Thermoset matrix natural fibre- reinforced composites
9.1 Introduction
9.2 Natural fibres used in thermoset matrix composites
9.3 Thermoset matrix types
9.4 Fabrication of thermoset matrix composites
9.5 Mechanical properties of synthetic resin composites
9.6 Bioderived resin composites
9.7 Applications of thermoset matrix natural fibre composites
9.8 Future trends

Part III: Testing and properties

Chapter 10: Non-destructive testing (NDT) of natural fibre composites: acoustic emission technique
10.1 Introduction
10.2 Using the acoustic emission (AE) technique in practice
10.3 Assessing results
10.4 Applications of AE
10.5 Future trends
10.6 Conclusions
10.7 Sources of further information and advice

Chapter 11: High strain rate testing of natural fiber composites
11.1 Introduction
11.2 Materials
11.3 Test methods
11.4 Results and discussion
11.5 Applications and future trends
11.6 Acknowledgments

Chapter 12: Performance of natural fiber composites under dynamic loading
12.1 Introduction
12.2 Natural fibers and natural fiber composites
12.3 Dynamic properties of natural fiber composites
12.4 Dynamic mechanical testing of natural fiber composites
12.5 Testing in practice: the example of pultruded natural fiber reinforced composites
12.6 Dynamic testing of composites
12.7 Performance of natural fiber reinforced composites under dynamic loading
12.8 Future trends
12.9 Acknowledgments

Chapter 13: The response of natural fibre composites to impact damage: a case study
13.1 Introduction
13.2 Mechanical characterization
13.3 Specimen preparation
13.4 Charpy impact test
13.5 Experimental results
13.6 Conclusion

Chapter 14: Natural fibre composites in a marine environment
14.1 Introduction
14.2 Properties and environmental impact of natural versus synthetic fibres
14.3 Natural fibre composites (NFCs) and moisture uptake
14.4 Geometrical considerations for plant fibres in NFCs
14.5 Marine applications of plant fibre composites14.6 Conclusions and future trends
14.7 Sources of further information and advice

Index 文章来源:http://chinacompositesexpo.com/cn/news.php?show=detail&c_id=288&news_id=4934