Analysis and Design of FRP Reinforced Concrete Structures

Chapter 1. Introduction<br/>1.1. Evolution of FRP Reinforcement<br/>1.2. Review of FRP Composites<br/>1.3. The Importance of the Polymer Matrix<br/>1.3.1. Matrix polymers<br/>1.3.2. Polyester resins<br/>1.3.3. Structural considerations in processing polymer matrix resins<br/>1.3.4. Reinforcing fibers for structural composites<br/>1.3.5. Effects of fiber length on laminate properties<br/>1.3.6. Bonding interphase<br/>1.3.7. Design considerations<br/>1.4. Description of Fibers<br/>1.4.1. Forms of glass fiber reinforcements<br/>1.4.2. Behavior of glass fibers under load<br/>1.4.3. Carbon fibers<br/>1.4.4. Aramid fibers<br/>1.4.5. Other organic fibers<br/>1.4.6. Hybrid reinforcements<br/>1.5. Manufacturing and Processing of Composites<br/>1.5.1. Steps of fabrication scheme<br/>1.5.2. Manufacturing methods<br/>1.6. Sandwich Construction<br/>1.7. Compression Molding<br/>1.8. Multi-Axial Fabric for Structural Components<br/>1.9. Fabrication of Stirrups<br/>1.10. FRP Composites<br/>1.11. FRP Composite Applications<br/>1.12. Composite Mechanics<br/>1.12.1. Laminate terminology<br/>1.12.2. Composite product forms<br/>1.13. Laminates Types and Stacking Sequence<br/>Chapter 2. Material Characteristics of FRP Bars<br/>2.1. Physical and Mechanical Properties<br/>2.2. Physical Properties<br/>2.3. Mechanical Properties and Behavior<br/>2.3.1. Tensile behavior<br/>2.3.2. Compressive behavior<br/>2.3.3. Shear behavior<br/>2.3.4. Bond behavior<br/>2.4. Time-Dependent Behavior<br/>2.4.1. Creep rupture<br/>2.4.2. Fatigue<br/>2.5. Durability<br/>2.6. Recommended Materials and Construction Practices<br/>2.6.1. Strength and modulus grades of FRP bars<br/>2.6.2. Surface geometry, bar sizes, and bar identification<br/>2.7. Construction Practices<br/>2.7.1. Handling and storage of materials<br/>2.7.2. Placement and assembly of materials<br/>2.8. Quality Control and Inspection<br/>Chapter 3. History and Uses of FRP Technology<br/>3.1. FRP Composites in Japan<br/>3.1.1. Development of FRP materials<br/>3.1.2. Development of design methods in Japan<br/>3.1.3. Typical FRP reinforced concrete structures in Japan<br/>3.1.4. FRP for retrofitting and repair<br/>3.1.5. Future uses of FRP<br/>3.1.6. FRP construction activities in Europe<br/>3.2. Reinforced and Prestressed Concrete: Some Applications<br/>3.2.1. Rehabilitation and strengthening<br/>3.2.2. Design guidelines<br/>3.3. FRP Prestressing in the USA<br/>3.3.1. Historical development of FRP tendons<br/>3.3.2. Research and demonstration projects<br/>3.3.3. Future prospects<br/>Chapter 4. Design of RC Structures Reinforced with FRP Bars<br/>4.1. Design Philosophy<br/>4.1.1. Design material properties<br/>4.1.2. Flexural design philosophy<br/>4.1.3. Nominal flexural capacity<br/>4.1.4. Strength reduction factor for flexure (ϕ)<br/>4.1.5. Check for minimum<br/>4.1.6. Serviceability<br/>4.2. Shear<br/>4.2.1. Shear design philosophy<br/>4.2.2. Shear failure modes<br/>4.2.3. Minimum shear reinforcement<br/>4.2.4. Shear failure due to crushing of the web<br/>4.2.5. Detailing of shear stirrups<br/>4.2.6. Punching shear strength of FRP reinforced, two-way concrete slab<br/>4.3. ISIS Canada Design Approach for Flexure<br/>4.3.1. Flexural strength<br/>4.3.2. Serviceability<br/>4.4. Design Approach for CFRP Prestressed Concrete Bridge Beams<br/>4.4.1. Theoretical development of design equations<br/>4.4.2 Deflection and stesses under service load condition<br/>4.4.3. Nonlinear response<br/>E4.1. Design Example 1<br/>E4.2. Design Example 2<br/>E4.3. Design Example 3<br/>E4.4. Design Example 4: A Case Study Problem<br/>E4.5. Design Example 5: Case Study of CFRP Prestressed Concrete Double-T Beam<br/>E4.6. Design Example 6: Case Study of Cfrp Prestressed Concrete Box-Beam<br/>E4.7. Design Example<br/>Chapter 5. Design Philosophy for FRP External Strengthening Systems<br/>5.1. Introduction<br/>5.1.1. Non-prestressed soffit plates<br/>5.1.2. End anchorage for unstressed (non-prestressed) plates<br/>5.1.3. Prestressed soffit