Performances and properties of steel and composite prestressed tendons – A review

Engineering

• Composite Material 100%
• Reinforced Plastic 100%
• Reinforced Concrete 66%
• Fiber-Reinforced Polymer Composite 66%
• Engineering 33%
• Manufacturing Process 33%
• Performance Characteristic 33%
• Corrosion Resistance 33%
• Combustibility 33%
• Carbon Fiber Reinforced Polymer 33%
• Ultimate Tensile Strength 33%
• Metallic Component 33%
• Aramid Fiber 33%
• Low Tensile Strength 33%
• Basalt Fiber 33%
• Elevated Temperature 33%
• Glass fiber reinforced polymer 33%

Keyphrases

• Tendon 100%
• Unbonded Tendons 100%
• Composite Materials 28%
• Fiber-reinforced Polymer Composites 28%
• Prestressed Reinforced Concrete 28%
• Manufacturing Process 14%
• Construction Industry 14%
• Valuable Resources 14%
• Limited Availability 14%
• Engineering Performance 14%
• Corrosion 14%
• Fiber Reinforced Polymer 14%
• Rust Resistance 14%
• Tensile Strength 14%
• Steel Tendon 14%
• Resistance to Elevated Temperature 14%
• Basalt Fiber-reinforced Polymer Tendon 14%
• Low Tensile Strength 14%
• Non-magnetic Properties 14%
• Lower Flammability Limit 14%
• Engineering Characteristics 14%
• Characteristic Evolution 14%
• Carbon Fiber-reinforced Polymer Tendons 14%
• Glass Fiber Reinforced Polymer 14%
• Characteristic Performance 14%
• Aramid Fiber Reinforced Polymer 14%
• Metallic Components 14%
• Steel Fiber 14%

Material Science

• Composite Material 100%
• Reinforced Plastic 100%
• Composite Material 42%
• Reinforced Concrete 28%
• Ultimate Tensile Strength 28%
• Polymer Composite 28%
• Corrosion 14%
• Rust 14%
• Glass Fiber 14%
• Carbon Fiber 14%
• Flammability 14%
• Magnetic Property 14%
• Aramid Fiber 14%