Table of Contents

Contributor contact details Preface Part I: Structure and properties of thermosets Chapter 1: Overview of thermosets: structure, properties and processing for advanced applications Abstract: 1.1 Introduction 1.2 Network formation in thermosets 1.3 Gelation, vitrification and transformation diagrams 1.4 Thermoset formulations and compounds 1.5 Processing of thermosets 1.6 Advanced materials based on thermosets 1.7 Conclusions Chapter 2: Mechanical properties of thermosets Abstract: 2.1 Introduction 2.2 Overview of thermoset classes 2.3 Thermal properties 2.4 Mechanical properties 2.5 Conclusions Chapter 3: Thermal properties of thermosets Abstract: 3.1 Introduction 3.2 Thermal conductivity 3.3 Thermal stability 3.4 Flammability and smoke property 3.5 Thermal cure characteristics 3.6 Glass transition temperature (Tg) 3.7 The influence of thermal properties on application 3.8 Thermal properties of toughened thermoset and composites 3.9 Conclusion Chapter 4: Rheology of thermosets: the use of chemorheology to characterise and model thermoset flow behaviour Abstract: 4.1 Introduction 4.1 Thermoset flow simulation and key material properties required 4.3 Thermoset processes and chemorheological models 4.4 Conclusions and future trends 4.5 Sources of further information and advice Chapter 5: Nanostructures and the toughening of thermosets Abstract: 5.1 Introduction 5.2 Nanostructure formation during polymerisation 5.3 Nanostructure formation by self-assembly before phase separation 5.4 Nanostructure formation by reaction-induced micro-phase separation (RIMPS) 5.5 Nanostructure formation by addition of nanoparticles 5.6 Nanostructure formation by addition of reactive polymers 5.7 Mechanism of toughening thermosets by nanostructuring 5.8 Conclusions 5.9 Acknowledgements Part II: Applications of thermosets Chapter 6: The use of thermosets in the building and construction industry Abstract: 6.1 Introduction 6.2 Thermal insulation 6.3 Applications of thermosets for piping and roofing 6.4 Other applications of unreinforced thermosets 6.5 Fiber-reinforced plastics (FRPs) 6.6 Applications of fiber-reinforced plastics (FRPs) 6.7 Polymer flammability 6.8 Future trends and development priorities 6.9 Sources of further information and advice 6.10 Acknowledgments Chapter 7: The use of thermosets in aerospace applications Abstract: 7.1 Introduction 7.2 Key requirements of materials used in the aerospace industry 7.3 The resin matrix 7.4 Applications and examples of thermosets for the aerospace industry 7.5 Composite tooling 7.6 Future trends and conclusions 7.7 Sources of further information and advice 7.8 Acknowledgements Chapter 8: Thermoset adhesives: epoxy resins, acrylates and polyurethanes Abstract: 8.1 Introduction 8.2 Epoxy-based thermosets 8.3 Polyurethane adhesives 8.4 Structural acrylic adhesives 8.5 Automotive and transportation applications of thermoset adhesives 8.6 Other applications of thermoset adhesives 8.7 Future trends 8.8 Acknowledgements Chapter 9: Thermoset insulation materials in appliances, buildings and other applications Abstract: 9.1 Introduction: the importance of energy conservation 9.2 Thermal insulation properties of thermoset foams 9.3 Thermoset polymers used in thermal insulation 9.4 Key requirements of thermoset insulation materials and products 9.5 Fabrication processes: pour-in-place and reaction injection molding 9.6 Fabrication processes: continuous lamination 9.7 Other fabrication processes 9.8 Applications and examples of thermoset insulation materials 9.9 Future trends and development priorities Chapter 10: Thermosets for electrical applications Abstract: 10.1 Introduction 10.2 Properties of thermosets 10.3 Oxidation, moisture and chemical resistance 10.4 Thermosets for electrical applications 10.5 Conclusions and future trends Index