Advanced Fibre Reinforced Polymer Frp Composites for Structural Applications 2nd Edition by Jiping Bai 0128203471 9780128203477
Original price was: $50.00.$35.00Current price is: $35.00.
Advanced Fibre Reinforced Polymer Frp Composites for Structural Applications 2nd Edition by Jiping Bai – Ebook PDF Instant Download/Delivery: 0128203471, 9780128203477
Full download Advanced Fibre Reinforced Polymer Frp Composites for Structural Applications 2nd Edition after payment
Product details:
ISBN 10: 0128203471
ISBN 13: 9780128203477
Author: Jiping Bai
Advanced Fibre-reinforced Polymer (FRP) Composites for Structural Applications, Second Edition provides updates on new research that has been carried out on the use of FRP composites for structural applications. These include the further development of advanced FRP composites materials that achieve lighter and stronger FRP composites, how to enhance FRP integrated behavior through matrix modification, along with information on pretension treatments and intelligence technology. The development of new technology such as automated manufacturing and processing of fiber-reinforced polymer (FRP) composites have played a significant role in optimizing fabrication processing and matrix formation.
In this new edition, all chapters have been brought fully up-to-date to take on the key aspects mentioned above. The book’s chapters cover all areas relevant to advanced FRP composites, from the material itself, its manufacturing, properties, testing and applications in structural and civil engineering. Applications span from civil engineering, to buildings and the energy industry.
- Covers all areas relevant to advanced FRP composites, from the material itself, its manufacturing, properties, testing and applications in structural engineering
- Features new manufacturing techniques, such as automated fiber placement and 3D printing of composites
- Includes various applications, such as prestressed-FRP, FRP made of short fibers, continuous structural health monitoring using advanced optical fiber Bragg grating (FBG), durability of FRP-strengthened structures, and the application of carbon nano-tubes or platelets for enhancing durability of FRP-bonded structures
Advanced Fibre Reinforced Polymer Frp Composites for Structural Applications 2nd Table of contents:
1: Introduction
Abstract
1.1: Climate emergency and the construction industry
1.2: Need for structural strengthening for structures
1.3: Fiber-reinforced polymers
1.4: Strengthening structures using FRP composites
1.5: Outline of the book
References
2: Polyester resins as a matrix material in advanced fiber-reinforced polymer (FRP) composites
Abstract
Acknowledgments
2.1: Introduction
2.2: Fiber-reinforced polymer (FRP) composites
2.3: Polyesters as matrix materials
2.4: Manufacture of polyester-based composites
2.5: Reinforcements for polyester-based composites
2.6: Applications of polymer-based composites
2.7: Conclusion and future trends
References
3: Vinylester resins as a matrix material in advanced fiber-reinforced polymer (FRP) composites
Abstract
3.1: Introduction
3.2: Vinylester and other resins as matrix materials
3.3: Fiber-reinforced polymer composites as structural materials
3.4: Fatigue, creep, and other properties of structural composites
3.5: Chemistry and properties of vinylester resins as matrix materials
3.6: Applications of vinylester-based composites in civil engineering
3.7: Conclusion and future trends
References
4: Characteristics of a new class of lightweight and tailorable 3D fiber metal laminates
Abstract
Acknowledgment
4.1: Introduction
4.2: Use of various metals in FMLs
4.3: Use of nonconventional fibers in FMLs
4.4: Current status of FML-related research
4.5: Recent advancement in FMLs
4.6: Future Trends
References
Further reading
5: Fiber-reinforced polymer types and properties
Abstract
5.1: Fiber-reinforced polymer materials
5.2: Matrix of FRP
5.3: Properties of FRP
References
6: Liquid composite molding processes
Abstract
6.1: Introduction
6.2: Process description
6.3: Simulation and experimental observations
6.4: Rigid molds
6.5: Flexible molds
6.6: Current usage
6.7: Case studies
6.8: Future trends
6.9: Summary
References
7: Pultrusion of advanced composites
Abstract
7.1: Introduction
7.2: Explanation
7.3: Procedure
7.4: Implications
7.5: Future trends
7.6: Summary
7.7: Sources of further information
References
8: Nanoindentation testing of epoxy polymer composites for fiber-reinforced applications
Abstract
Acknowledgments
8.1: Introduction
8.2: Materials and methods
8.3: Results and discussion
8.4: Conclusions
8.5: Future trends and advice
References
9: Understanding and predicting stiffness in advanced fiber-reinforced polymer (FRP) composites for structural applications
Abstract
9.1: Introduction
9.2: General aspects of composite stiffness
9.3: Understanding lamina stiffness
9.4: Micromechanical analysis of a Lamina
9.5: Comparing micromechanical models with experimental data
9.6: Stiffness and compliance transformations
9.7: Laminate plate and shell stiffness: Classical lamination theory (CLT)
9.8: Properties of different types of laminate
9.9: Master ply concept
9.10: In-plane and flexural engineering constants of a laminate
9.11: An image-driven approach for measuring laminate stiffness
9.12: Conclusions and future trend
9.13: Sources of further information and advice
References
10: Understanding the durability of advanced fiber-reinforced polymer (FRP) composites for structural applications
Abstract
10.1: Introduction
10.2: Structure and processing of fiber-reinforced polymer (FRP) composites
10.3: Applications of FRP composites in civil engineering
10.4: Physical aging: Mechanisms and stabilization techniques
10.5: Mechanisms of chemical aging: Introduction
10.6: Mechanisms of chemical aging: Reaction–diffusion coupling
10.7: Mechanisms of chemical aging: Hydrolytic processes
10.8: Mechanisms of chemical aging: Oxidation processes
10.9: Chemical aging: Stabilization techniques
10.10: Fiber and interfacial degradation
10.11: Flammability of FRP composites
10.12: Improving the fire retardancy of FRP composites
10.13: Structural integrity of FRP composites exposed to fire
10.14: Conclusion and future trends
10.15: Sources of further information and advice
References
11: Testing of pultruded glass fiber-reinforced polymer (GFRP) composite materials and structures
Abstract
Acknowledgments
11.1: Introduction
11.2: Tests to characterize the mechanical properties of pultruded glass fiber-reinforced polymer (GFRP) material
11.3: Tests to characterize the flexural, torsional, buckling, and collapse responses of pultruded GFRP structural grade profiles
11.4: Tests to characterize the stiffness and strength of pultruded GFRP joints
11.5: Tests on pultruded GFRP sub- and full-scale structures
11.6: Conclusion
11.7: Brief selection of further information and advice
References
12: Nanofiber interleaving in fiber-reinforced composites for toughness improvement
Abstract
12.1: Introduction
12.2: Interleaving for toughness improvement
12.3: Conclusions and future perspectives
References
13: Design of fiber-reinforced polymer for strengthening structures
Abstract
13.1: Introduction
13.2: Choice of materials for design
13.3: Modes of failure
13.4: Structural analysis for design
13.5: Basis of design
13.6: Design guidance
References
14: Advanced fiber-reinforced polymer composites to enhance seismic response of existing structures
Abstract
14.1: Introduction
14.2: Seismic behavior of existing RC structures
14.3: FRP-retrofitting systems to enhance the seismic response of RC structures
14.4: Proposed damage-controllable performance of FRP-retrofitted structures
14.5: Seismic response of FRP-retrofitted RC structures
14.6: Summary and future trends
References
Further reading
15: Fiber-reinforced concrete (FRC) for civil engineering applications
Abstract
Acknowledgments
15.1: Historical perspective
15.2: Physical and chemical effects of fibers in concrete
15.3: Mechanical effects of fibers in concrete
15.4: Special applications of FRC and future trends
15.5: Conclusions
References
16: Advanced fiber-reinforced polymer (FRP) composite materials in bridge engineering: Materials, properties and applications in bridge enclosures, reinforced and prestressed concrete beams and columns
Abstract
16.1: Introduction
16.2: Fiber-reinforced polymer (FRP) materials used in bridge engineering
16.3: In-service and physical properties of FRP composites used in bridge engineering
16.4: FRP bridge enclosures
16.5: FRP bridge decks
16.6: The rehabilitation of reinforced concrete (RC) and prestressed concrete (PC) bridge beams using external FRP plate bonding (EPB)
16.7: FRP rebars/grids and tendons as an alternative to steel for reinforcing concrete beams in highway bridges
16.8: Seismic retrofit of columns and shear strengthening of RC bridge structures
16.9: Conclusion and future trends
16.10: Sources of further information and advice
References
Further reading
17: Applications of advanced fiber-reinforced polymer (FRP) composites in bridge engineering: Rehabilitation of metallic bridge structures, all-FRP composite bridges, and bridges built with hybrid systems
Abstract
17.1: Introduction
17.2: The rehabilitation of metallic bridge beams
17.3: Composite patch repair for metallic bridge structures
17.4: All-fiber-reinforced polymer (FRP) composite bridge superstructure
17.5: New bridge construction with hybrid systems
17.6: Conclusion and future trends
17.7: Sources of further information and advice
References
18: Advanced fiber-reinforced polymer (FRP) composite materials for sustainable energy technologies
Abstract
Acknowledgments
18.1: Introduction: Current use of composite materials in sustainable energy technology
18.2: The use of nanoparticles in composites
18.3: In-service requirements of advanced FRP composites for sustainable energy applications
18.4: Manufacture of FRP composite materials for sustainable energy systems
18.5: Composite materials/fabrication techniques used for wind turbines
18.6: Composite materials/fabrication techniques for tidal energy power generators
18.7: Composite materials/fabrication techniques for solar energy applications
18.8: Conclusion and future trends
18.9: Sources of further information and advice
References
19: Sustainable energy production: Key material requirements
Abstract
Acknowledgments
19.1: General introduction
19.2: Introduction to wind turbines
19.3: Introduction to hydropower
19.4: Introduction to solar power
19.5: Introduction to biomass and geothermal energies
19.6: Discussion
19.7: Conclusion
References
20: Improving the performance of advanced fiber-reinforced polymer (FRP) composites using nanoclay
Abstract
Acknowledgement
20.1: Introduction
20.2: Materials and fabrication
20.3: Experimental
20.4: Result and discussion
20.5: Fracture toughness assessment
20.6: Conclusion
References
21: Advanced fiber-reinforced polymer (FRP) composites for the rehabilitation of timber and concrete structures: Assessing strength and durability
Abstract
Acknowledgments
21.1: Introduction
21.2: Composite rehabilitation systems
21.3: Metallic and masonry structures
21.4: Performance and durability
21.5: Conclusion and future trends
21.6: Sources of further information and advice
References
Index
People also search for Advanced Fibre Reinforced Polymer Frp Composites for Structural Applications 2nd :
advanced fibre reinforced polymer frp composites for structural applications
advanced fibre reinforced polymer frp composites for structural applications pdf
what is fiber reinforced polymer composites
what is fiber reinforced polymer
Tags:
Jiping Bai,Advanced Fibre,Reinforced Polymer