About the authors
Preface
Acknowledgments
1.Development of melt electrospinning: the past, present, and future
1.1 Electrospinning
1.2 The working principle of electrospinning
1.3 Types of electrospinning
1.4 Solution electrospinning
1.5 Melt electrospinning
1.6 The scope of this book
References
2.The device of melt electrospinning
2.1 Introduction
2.2 Conventional melt electrospinning devices
. Laser heating melt electrospinning devices
2.4 Screw extrusion melting electrostatic spinning devices
2.5 Electromagnetic spinning devices for vibration
2.6 Air melt electrospinning devices
2.7 Coaxial melt electrosplnning devices
2.8 Upward melt electrospinning devices
2.9 Centrifugal melt electrospinning devices
2.10 Conclusion
References
3.Formation of fibrous structure and influential factors in melt electrospinning
3.1 Polycaprolactone
3.1 .I Experiment
3.1.2 Results ~nd discussion
3.2 Polylactic acid (PLA)
3.2.1 The diameter of PLLA fiber under a pulsed electric field
3.2.2 Thermal degradation of PLA fiber
3.. The relative molecular mass of PLA fibers
3.2.4 Orientation and crystallinity of the PLA fiber
3.3 Phenolic resin
3.3.1 Materials and equipment
3.3.20 rthogona xermetal arrangements
3.3.3 Optimal spinnin onitions
3.3.4 Fiber heat resistance and crystallinity
3.3.5 Session conclusion
3.4 Polypropylene (PP)
3.4.1 Equipment
3.4.2 Effect of collecting plate on spinning electric field
3.4.3 Effect of upper plate on spinning electric field
3.4.4 Effect of the hyperbranched polymers
3.4.5 Effect of polar additive on PP
3.5 Conclusion
References
Further reading
4.Melt electrospinning in a parallel electric field
4.1 Introduction
4.2 Method and experiments
4.2.1 Experimental material
4.2.2 Parallel electrospinning equipment
4.. Finite element modeling
4.2.4 Theoretical analysis
4.3 Results and discussion
4.3.1 Experimental electrospinning in a parallel electric field
4.3.2 Finite element simulation of the electrospinning process in a parallel electric field
4.4 Conclusion
References
5.Dissipative particle dynamics simulation on melt electrospinning
5.1 Introduction
5.2 Differential scanning calorimetry simulation under different electric fields
5.2.1 Electrostatic field
5.2.2 Pulsed electric field
5.3 Conclusion
References
6.Experimental study on centrifugal melt electrospinning
6.1 Overview of centrifugal melt electrospinning
6.2 Research progress of centrifugal melt electrospinning at home and abroad
6.3 The significance of centrifugal melt electrospinning devices
6.4 Experimental study on centrifugal melt electrospinning
6.4.1 Experimental section
6.4.2 Characterization method
6.4.3 Results and discussion
6.5 Innovative design of centrifugal melt electrospinning devices
6.6 Conclusion
References
7.Dissipative particle dynamics simulations of centrifugal melt electrospinning
7.1 Introduction
7.2 The dissipative particle dynamics model in centrifugal melt electrospinning
7.3 Different electric field simulation of centrifugal melt electrospinning
7.3.1 Centrifugal melt electrospinning in an electrostatic field
7.3.2 Centrifugal melt electrospinning in a pulsed electric field
7.4 Conclusion
References
8.Three-dimensional (3D) printing based on controlled melt electrospinning in polymeric biomedical materials
8.1 Introduction
8.2 Basic principles of 3D printing based on electrospinning
8.3 Different auxiliary electrode and dielectric plate collectors
8.3.1 Setup for electrospinning with an electrostatic lens system
8.3.2 Dielectric plate with sharp-pin electrode
8.4 Patterned, tubular, and porous nanofiber
8.5 Conclusion
References
Index
随着纳米新材料科技的持续发展,高分子基纳米复合纤维在燃料电池、锂电池、太阳能电池、水过滤、空气过滤、血液过滤、组织工程、载药缓释、癌症检测、介入治疗支架、人造血管、金属吸附等领域得到了广泛研究。静电纺丝作为制备纳米纤维简单、直接、有效的方法,在国内外得到了普遍重视和广泛研究。其中熔体静电纺丝,相对于得到广泛普及的溶液静电纺丝来说,因不使用挥发有机溶剂而具有经济、安全、绿色环保等特点。本书为作者带领课题组成员多年来对熔体静电纺丝设备、原理及技术方法进行探索的成果总结,是原创英文专著。
本书特点:
1. 作者知名。刘勇教授(北京化工大学材料学院高分子纳米复合材料实验室负责人)和新加坡工程院Seeram Ramakrishna院士(静电纺丝技术制备纳米纤维领域世界认可的和开拓者,也是英皇工程院外籍院士、印度工程院院士,东盟工程技术院院士)的团队,是近年来熔体静电纺丝领域活跃和成果丰富的研究团队。
2. 内容原创。基于作者多年的原创科研成果,对熔体静电纺丝技术做了全面的总结。
3. 技术内容全面。介绍了熔体静电纺丝的发明,包括离心熔体静电纺丝和向上熔体静电纺丝。阐述了优化技术、聚合物熔体静电纺丝、测试方法、耗散粒子动力学模拟和改进方法。
4. 思路创新。提供了一个对当代静电纺丝研究及其许多潜在应用的有益的和独特的介绍。
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