Table of Contents

- Contributor contact details - Woodhead Publishing Series in Energy - Preface - Part I: Reactor pressure vessel (RPV) design and fabrication - 1: Reactor pressure vessel (RPV) design and fabrication: the case of the USA - Abstract - 1.1 Introduction - 1.2 American Society of Mechanical Engineers (ASME) Code design practices - 1.3 The design process - 1.4 Reactor pressure vessel (RPV) materials selection - 1.5 Toughness requirements - 1.6 RPV fabrication processes - 1.7 Welding practices - 2: Reactor pressure vessel (RPV) components: processing and properties - Abstract - 2.1 Introduction - 2.2 Advances in nuclear reactor pressure vessel (RPV) components - 2.3 Materials for nuclear RPVs - 2.4 Manufacturing technologies - 2.5 Metallurgical and mechanical properties of components - 2.6 Conclusions - 3: WWER-type reactor pressure vessel (RPV) materials and fabrication - Abstract - 3.1 Introduction - 3.2 WWER reactor pressure vessel (RPV) materials - 3.3 Production of materials for components and welding techniques - 3.4 Future trends - Part II: Reactor pressure vessel (RPV) embrittlement in operational nuclear power plants - 4: Embrittlement of reactor pressure vessels (RPVs) in pressurized water reactors (PWRs) - Abstract - 4.1 Introduction - 4.2 Characteristics of pressurized water reactor (PWR) reactor pressure vessel (RPV) embrittlement - 4.3 US surveillance database - 4.4 French surveillance database - 4.5 Japanese surveillance database - 4.6 Surveillance databases from other countries - 4.7 Future trends - 5: Embrittlement of reactor pressure vessels (RPVs) in WWER-type reactors - Abstract - 5.1 Introduction - 5.2 Characteristics of embrittlement of WWER reactor pressure vessel (RPV) materials - 5.3 Trend curves - 5.4 WWER surveillance programmes - 5.5 RPV annealing in WWER reactors - 5.6 RPV annealing technology - 5.7 Sources of further information and advice - 6: Integrity and embrittlement management of reactor pressure vessels (RPVs) in light-water reactors - Abstract - 6.1 Introduction - 6.2 Parameters governing reactor pressure vessel (RPV) integrity - 6.3 Pressure–temperature operating limits - 6.4 Pressurized thermal shock (PTS) - 6.5 Mitigation methods - 6.6 Licensing considerations - 7: Surveillance of reactor pressure vessel (RPV) embrittlement in Magnox reactors - Abstract - 7.1 Introduction - 7.2 History of Magnox reactors - 7.3 Reactor pressure vessel (RPV) materials and construction - 7.4 Reactor operating rules - 7.5 Design of the surveillance schemes - 7.6 Early surveillance results - 7.7 Dose–damage relationships and intergranular fracture in irradiated submerged-arc welds (SAWs) - 7.8 Influence of thermal neutrons - 7.9 Validation of toughness assessment methodology by RPV SAW sampling - 7.10 Final remarks - 7.11 Acknowledgements - Part III: Techniques for the evaluation of reactor pressure vessel (RPV) embrittlement - 8: Irradiation simulation techniques for the study of reactor pressure vessel (RPV) embrittlement - Abstract - 8.1 Introduction - 8.2 Test reactor irradiation - 8.3 Ion irradiation - 8.4 Electron irradiation - 8.5 Advantages and limitations - 8.6 Future trends - 8.7 Sources of further information and advice - 9: Microstructural characterisation techniques for the study of reactor pressure vessel (RPV) embrittlement - Abstract - 9.1 Introduction - 9.2 Microstructural development and characterisation techniques - 9.3 Transmission electron microscopy (TEM) - 9.4 Small-angle neutron scattering (SANS) - 9.5 Atom probe tomography (APT) - 9.6 Positron annihilation spectroscopy (PAS) - 9.7 Auger electron spectroscopy (AES) - 9.8 Other techniques - 9.9 Using microstructural analyses to understand the mechanisms of reactor pressure vessel (RPV) embrittlement - 9.10 Grain boundary segregation - 9.11 Matrix damage - 9.12 Solute clusters - 9.13 Mechanistic framework to develop dose–damage relationships (DDRs) - 9.