Properties and Testing of Fiber-Reinforced Polymers
1. Auflage
Erschienen am 25. Februar 2026
352 Seiten
978-3-527-85217-8 (ISBN)
Beschreibung
Discover essential knowledge for testing polymer composites in this book by experts Yasushi Miyano
and Masayuki Nakada. They provide vital insights for materials scientists and engineers. Perfect for anyone in the aircraft, marine, and automobile industries.
and Masayuki Nakada. They provide vital insights for materials scientists and engineers. Perfect for anyone in the aircraft, marine, and automobile industries.
Weitere Details
Weitere Ausgaben
Andere Ausgaben
Yasushi Miyano | Masayuki Nakada
Properties and Testing of Fiber-Reinforced Polymers
Buch
04/2026
1. Auflage
Wiley-VCH
149,00 €
Sofort lieferbar
Personen
Yasushi Miyano and Masayuki Nakada are Professors in Materials System Research Laboratory at Kanazawa Institute of Technology, Japan. Their research is focused on the prediction methodology for the long-term creep and fatigue lives of polymer composites based on the time-temperature superposition principle. Prof. Miyano is fellow of the Society for the Advancement of Material & Process Engineering, The Japan Society of Mechanical Engineers, and The Japan Society of Composite Materials. Prof. Nakada is a fellow of The Japan Society of Composite Materials.
Inhalt
Preface
PART I Accelerated Testing Methodology (ATM)
1 INTRODUCTION
2 VISCOELASTICITY
2.1 Introduction
2.2 Concept of Viscoelastic Behavior
2.3 Concept of Time-Temperature Superposition Principle
2.4 Master Curve of Creep Compliance of Matrix Resin
2.5 Generalization of TTSP for Nondestructive Deformation Properties to Static, Creep, and Fatigue Strengths of FRPs
2.6 Master Curve of Static Strength of FRP
2.7 Master Curve of Creep Strength of FRP
2.8 Master Curve of Fatigue Strength of FRP
2.9 Conclusion
3 MASTER CURVES OF VISCOELASTIC COEFFICIENTS OF MATRIX RESIN
3.1 Introduction
3.2 Master Curves of Creep Compliance Based on Modified TTSP
3.3 Simplified Determination of Long-Term Viscoelastic Behavior
3.4 Master Curve of Relaxation Modulus by DMA and Creep Tests
3.5 Conclusion
4 NONDESTRUCTIVE MECHANICAL PROPERTIES OF FRP
4.1 Introduction
4.2 Role of Mixture
4.3 Mechanical and Thermal Properties of Unidirectional CFRPs, Fibers and Matrix Resin
4.4 Master Curves of Creep Compliance of Matrix Resin
4.5 Conclusion
5 STATIC AND FATIGUE STRENGTHS OF FRP
5.1 Introduction
5.2 Experimental Procedures
5.3 Results and Discussion
5.4 Applicability of TTSP
5.5 Conclusion
6 APPLICATION 1 OF ATM: STATIC AND FATIGUE FLEXURAL STRENGTHS OF VARIOUS FRP LAMINATES UNDER WATER ABSORPTION CONDITION
6.1 Introduction
6.2 Specimen Preparation
6.3 Experimental Procedures
6.4 Creep Compliance
6.5 Flexural Static Strength
6.6 Flexural Fatigue Strength
6.7 Conclusion
7 APPLICATION 2 OF ATM: LIFE PREDICTION OF CFRP/METAL BOLTED JOINT
7.1 Introduction
7.2 Experimental Procedures
7.3 Results and Discussion
7.4 Conclusion
PART II Advanced Accelerated Testing Methodology (Advanced ATM)
8 INTRODUCTION
9 FORMULATION OF STATIC STRENGTH OF FRP
9.1 Introduction
9.2 Formulation of Static Strength
9.3 Application of Formulation
9.4 Results and Discussion
9.5 Conclusion
10 FORMULATION OF FATIGUE STRENGTH OF FRP
10.1 Introduction
10.2 Formulation
10.3 Application of Formulation
10.4 Conclusion
11 FORMULATION OF CREEP STRENGTH OF FRP
11.1 Introduction
11.2 Formulation
11.3 Application of Formulation
11.4 Conclusion
12 APPLICATION 1 OF ADVANCED ATM: STATIC STRENGTHS IN VARIOUS LOAD DIRECTIONS OF UNIDIRECTIONAL CFRP UNDER WATER ABSORPTION CONDITION
12.1 Introduction
12.2 Experimental Procedures
12.3 Viscoelastic Behavior of Matrix Resin
12.4 Master Curves of Static Strengths for Unidirectional CFRP Laminates
12.5 Relation between Static Strengths and Viscoelasticity of Matrix Resin
12.6 Conclusion
13 APPLICATION 2 OF ADVANCED ATM: LIFE PREDICTION OF CFRP STRUCTURES BASED ON MMF/ATM METHOD
13.1 Introduction
13.2 Procedure of MMF/ATM Method
13.3 Determination of MMF/ATM Critical Parameters
13.4 Life Determination of CFRP Structures Based on MMF/ATM Method
13.5 Experimental Confirmation for OHC Static and Fatigue Strengths of CFRP QILs
13.6 Conclusion
14. APPLICATION 3 OF ADVANCED ATM: EFFECT OF MOLDING CONDITION ON STATISTICAL STATIC
AND CREEP STRENGTHS OF CFRP STRAND
14.1 Introduction
14.2 Experiments
14.3 Creep Compliance of Matrix Resin and Static Strength of CFRP Strand
14.4. Master Curves of Statistical Static and Creep Strengths of CFRP Strands
14.5 Conclusion
15 APPLICATION 4 OF ADVANCED ATM: EFFECT OF CARBON FIBER ON STATISTICAL STATIC AND CREEP STRENGTHS OF CFRP STRAND
15.1 Introduction
15.2 Molding of CFRP Strands and Testing Methods
15.3 Results and Discussion
15.4 Conclusion
PART III Integrated Accelerated Testing Methodology (Integrated ATM)
16 INTRODUCTION
17 INTEGRATED ATM
17.1 Introduction
17.2 Formulation
17.3 Application of Integrated ATM
17.4 Statistical Long-Term Life Prediction of CFRP Strand
17.5 Conclusion
18 APPLICATION 1 OF INTEGRATED ATM: STATISTICAL CREEP AND FATIGUE LIVES OF UNIDIRECTIONAL CFRP LAMINATES UNDER BENDING LOAD
18.1 Introduction
18.2 Experiments
18.3 Results an
PART I Accelerated Testing Methodology (ATM)
1 INTRODUCTION
2 VISCOELASTICITY
2.1 Introduction
2.2 Concept of Viscoelastic Behavior
2.3 Concept of Time-Temperature Superposition Principle
2.4 Master Curve of Creep Compliance of Matrix Resin
2.5 Generalization of TTSP for Nondestructive Deformation Properties to Static, Creep, and Fatigue Strengths of FRPs
2.6 Master Curve of Static Strength of FRP
2.7 Master Curve of Creep Strength of FRP
2.8 Master Curve of Fatigue Strength of FRP
2.9 Conclusion
3 MASTER CURVES OF VISCOELASTIC COEFFICIENTS OF MATRIX RESIN
3.1 Introduction
3.2 Master Curves of Creep Compliance Based on Modified TTSP
3.3 Simplified Determination of Long-Term Viscoelastic Behavior
3.4 Master Curve of Relaxation Modulus by DMA and Creep Tests
3.5 Conclusion
4 NONDESTRUCTIVE MECHANICAL PROPERTIES OF FRP
4.1 Introduction
4.2 Role of Mixture
4.3 Mechanical and Thermal Properties of Unidirectional CFRPs, Fibers and Matrix Resin
4.4 Master Curves of Creep Compliance of Matrix Resin
4.5 Conclusion
5 STATIC AND FATIGUE STRENGTHS OF FRP
5.1 Introduction
5.2 Experimental Procedures
5.3 Results and Discussion
5.4 Applicability of TTSP
5.5 Conclusion
6 APPLICATION 1 OF ATM: STATIC AND FATIGUE FLEXURAL STRENGTHS OF VARIOUS FRP LAMINATES UNDER WATER ABSORPTION CONDITION
6.1 Introduction
6.2 Specimen Preparation
6.3 Experimental Procedures
6.4 Creep Compliance
6.5 Flexural Static Strength
6.6 Flexural Fatigue Strength
6.7 Conclusion
7 APPLICATION 2 OF ATM: LIFE PREDICTION OF CFRP/METAL BOLTED JOINT
7.1 Introduction
7.2 Experimental Procedures
7.3 Results and Discussion
7.4 Conclusion
PART II Advanced Accelerated Testing Methodology (Advanced ATM)
8 INTRODUCTION
9 FORMULATION OF STATIC STRENGTH OF FRP
9.1 Introduction
9.2 Formulation of Static Strength
9.3 Application of Formulation
9.4 Results and Discussion
9.5 Conclusion
10 FORMULATION OF FATIGUE STRENGTH OF FRP
10.1 Introduction
10.2 Formulation
10.3 Application of Formulation
10.4 Conclusion
11 FORMULATION OF CREEP STRENGTH OF FRP
11.1 Introduction
11.2 Formulation
11.3 Application of Formulation
11.4 Conclusion
12 APPLICATION 1 OF ADVANCED ATM: STATIC STRENGTHS IN VARIOUS LOAD DIRECTIONS OF UNIDIRECTIONAL CFRP UNDER WATER ABSORPTION CONDITION
12.1 Introduction
12.2 Experimental Procedures
12.3 Viscoelastic Behavior of Matrix Resin
12.4 Master Curves of Static Strengths for Unidirectional CFRP Laminates
12.5 Relation between Static Strengths and Viscoelasticity of Matrix Resin
12.6 Conclusion
13 APPLICATION 2 OF ADVANCED ATM: LIFE PREDICTION OF CFRP STRUCTURES BASED ON MMF/ATM METHOD
13.1 Introduction
13.2 Procedure of MMF/ATM Method
13.3 Determination of MMF/ATM Critical Parameters
13.4 Life Determination of CFRP Structures Based on MMF/ATM Method
13.5 Experimental Confirmation for OHC Static and Fatigue Strengths of CFRP QILs
13.6 Conclusion
14. APPLICATION 3 OF ADVANCED ATM: EFFECT OF MOLDING CONDITION ON STATISTICAL STATIC
AND CREEP STRENGTHS OF CFRP STRAND
14.1 Introduction
14.2 Experiments
14.3 Creep Compliance of Matrix Resin and Static Strength of CFRP Strand
14.4. Master Curves of Statistical Static and Creep Strengths of CFRP Strands
14.5 Conclusion
15 APPLICATION 4 OF ADVANCED ATM: EFFECT OF CARBON FIBER ON STATISTICAL STATIC AND CREEP STRENGTHS OF CFRP STRAND
15.1 Introduction
15.2 Molding of CFRP Strands and Testing Methods
15.3 Results and Discussion
15.4 Conclusion
PART III Integrated Accelerated Testing Methodology (Integrated ATM)
16 INTRODUCTION
17 INTEGRATED ATM
17.1 Introduction
17.2 Formulation
17.3 Application of Integrated ATM
17.4 Statistical Long-Term Life Prediction of CFRP Strand
17.5 Conclusion
18 APPLICATION 1 OF INTEGRATED ATM: STATISTICAL CREEP AND FATIGUE LIVES OF UNIDIRECTIONAL CFRP LAMINATES UNDER BENDING LOAD
18.1 Introduction
18.2 Experiments
18.3 Results an
