Sale!

Active Coatings for Smart Textiles 1st Edition by Jinlian Hu ISBN 0081002637 978-0081002636

Name: Active Coatings for Smart Textiles 1st Edition by Jinlian Hu ISBN 0081002637 978-0081002636
SKU: EB-5431988
Availability: InStock

Original price was: $50.00.Current price is: $25.00.

Active Coatings for Smart Textiles 1st Edition Hu Digital Instant Download

Author(s): Hu, Jinlian

ISBN(s): 9780081002636, 9780081002650, 9780857098399, 9780857098436, 9780857098528, 0081002637, 0081002653, 085709839X, 0857098438

Edition: 1

File Details: PDF, 40.21 MB

Year: 2016

Language: English

SKU: EB-5431988 Category: Engineering Tags: Hu, Jinlian

Description

Active Coatings for Smart Textiles 1st Edition by Jinlian Hu – Ebook PDF Instant Download/Delivery: 0081002637, 978-0081002636

Full download Active Coatings for Smart Textiles 1st Edition after payment

Product details:

ISBN 10: 0081002637

ISBN 13: 978-0081002636

Author: Jinlian Hu

Active Coatings for Smart Textiles presents the latest information on active materials and their application to textiles in the form of coatings and finishes for the purpose of improving performance and creating active functional effects. This important book provides detailed coverage of smart coating types, processes, and applications.

After an introduction to the topic, Part One introduces various types of smart and active coatings, including memory polymer coatings, durable and self-cleaning coatings, and breathable coatings. Technologies and related processes for the application of coatings to textiles is the focus of Part Two, with chapters devoted to microencapsulation technology, plasma surface treatments, and nanotechnology-based treatments.

The book ends with a section on applications of smart textiles with responsive coatings, which are increasingly finding commercial niches in sportswear, protective clothing, medical textiles, and architecture.

Introduces various types of smart and active coatings for textiles
Covers technologies and application processes for the coating and finishing of textiles
Reviews commercial applications of such coatings, including in sportswear, protective clothing, medical textiles and architecture

Introduction to active coatings for smart textiles
1.1. Introduction
1.2. Functions and applications of active coating
1.3. Development of smart materials for active coating
1.4. Development of processing technologies for active coating
1.5. Outline of the book
Memory polymer coatings for smart textiles
2.1. Introduction
2.2. Memory polymers
2.3. Functions of memory coating textiles
2.4. Conclusions
Environmentally mild self-cleaning processes on textile surfaces under daylight irradiation: Critical issues
3.1. Introduction: self-cleaning of textiles by mild environmental sunlight-activated processes
3.2. Pretreatment by and functionalization of surfaces by radiofrequency plasma and ultraviolet-C (184 nanomoles)
3.3. Coating by colloidal titanium dioxide of artificial fibers such as polyamide and polyester: evaluation of self-cleaning performance under low-intensity solar irradiation
3.4. Coating by colloidal titanium dioxide of natural fibers: evaluation of self-cleaning performance under low-intensity solar irradiation
3.5. Cotton self-cleaning by titanium dioxide clusters attached by chemical spacers under low-intensity solar irradiation
3.6. Self-cleaning cotton textiles titanium dioxide–modified by silicon dioxide–protective layers
3.7. Coatings by binary oxides and/or promoted or enhanced copper-binary oxides leading to faster stain discoloration under low-intensity solar irradiation: reaction mechanism and surface characterization
3.8. Trend of work in this area: future directions
Smart durable and self-healing textile coatings
4.1. Introduction
4.2. Types and classifications of smart coatings for improving textile durability
4.3. Properties of textiles with durability-enhancing coatings
4.4. Applications of smart durable and self-healing textiles
4.5. Future trends
4.6. Conclusions
Smart breathable coatings for textiles
5.1. Introduction
5.2. Working principles of smart breathable coatings
5.3. Materials for breathable coating
5.4. Methods of generating hydrophilic and microporous coatings
5.5. Testing and evaluation of different breathable coated fabrics
5.6. Applications
5.7. Conclusions and future trends
Conductive polymer coatings
6.1. Introduction
6.2. Conductive polymers for textile coating
6.3. Properties and applications of conducting polymers
6.4. Conclusion
Natural photonic materials for textile coatings
7.1. Introduction
7.2. Types and classifications of natural photonic materials
7.3. Photonic structures brought to textile coating
7.4. Structural-colored sensors by external stimuli
7.5. Summary and outlook

Part Two. Smart coating processes and technologies

Coating processes and techniques for smart textiles
8.1. Introduction
8.2. Substrate and coating interactions
8.3. Overview of coating
8.4. Traditional processes for textile coating
8.5. Coating for smart textiles
8.6. Future trends
Microencapsulation technology for smart textile coatings
9.1. Introduction
9.2. Benefits of microencapsulation for textiles
9.3. Microencapsulation technologies
9.4. Application procedures of microcapsules on textile substrate
9.5. Smart end uses of textile substrates containing microcapsules
9.6. Conclusions
Plasma surface treatments for smart textiles
10.1. Introduction
10.2. Principles of plasma creation
10.3. Plasma–substrate interactions
10.4. Applications of plasma surface treatments in smart textiles
10.5. Future trends
10.6. Conclusion
Nanotechnology-based coating techniques for smart textiles
11.1. Introduction
11.2. Types and classifications of nanotechnology-based coating techniques
11.3. Nanofibre coating via electrospinning
11.4. Future trends
11.5. Conclusion
Biomimetic nanocoatings for structural coloration of textiles
12.1. Introduction
12.2. Characterization of biomimetic structural coloration
12.3. Structural colors of thin-film interference on textiles with electrostatic self-assembly
12.4. Structural colors of photonic crystals on textiles
12.5. Conclusions and future trends
Functional modification of fiber surface via sol–gel technology
13.1. Introduction
13.2. Hydrophobic and oleophobic modifications
13.3. Anti-ultraviolet property using titanium dioxide hybrid sol
13.4. Antibacterial finishing using cationic or titanium dioxide hybrid sol
13.5. Color fixation using smart silane coupling agent hybrid sol
13.6. Conclusion

Part Three. Applications of smart textiles with responsive coatings

Smart coatings for comfort in clothing
14.1. Introduction
14.2. Principles of comfort in textiles and clothing
14.3. Technologies for smart textile coatings
14.4. Functions of smart textile/apparel coatings
14.5. Future trends
14.6. Conclusion
Smart coatings for sportswear
15.1. Introduction
15.2. Smart coating and functional requirements of sportswear
15.3. Smart coatings to enhance comfort in sportswear
15.4. Smart coating to provide protection
15.5. Smart coating for performance enhancement
15.6. Smart textiles for health and motion monitoring in sportswear
15.7. Conclusions
Smart coatings for protective clothing
16.1. Introduction
16.2. Smart coating for body armor application
16.3. Smart coating for hazardous material protective clothing
16.4. Smart coating for health care protective clothing
16.5. Smart coating for firefighter protective clothing
16.6. Future trends
Smart medical textiles based on cyclodextrins for curative or preventive patient care
17.1. Introduction
17.2. Cyclodextrin production, binding properties, and applications
17.3. Cyclodextrins grafted on textiles for medical purposes
17.4. Conclusion and perspectives
Smart coatings for textiles in architecture
18.1. Introduction
18.2. Current trends in advanced architecture and smart textiles for architectural applications
18.3. Current components and types of smart-coated textiles for architectural applications
18.4. Future trends in advanced architecture and smart textiles for architectural applications
18.5. Applications for interior, exterior use and for actuators