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Gaseous Hydrogen Embrittlement of Materials in Energy Technologies
The Problem, its Characterisation and Effects on Particular Alloy Classes
Richard P Gangloff (Edited by), Brian P Somerday (Edited by)
9780081016237
Paperback, published 19 August 2016
864 pages
23.3 x 15.6 x 5.2 cm, 1.19 kg
Many modern energy systems are reliant on the production, transportation, storage, and use of gaseous hydrogen. The safety, durability, performance and economic operation of these systems is challenged by operating-cycle dependent degradation by hydrogen of otherwise high performance materials. This important two-volume work provides a comprehensive and authoritative overview of the latest research into managing hydrogen embrittlement in energy technologies.
Volume 1 is divided into three parts, the first of which provides an overview of the hydrogen embrittlement problem in specific technologies including petrochemical refining, automotive hydrogen tanks, nuclear waste disposal and power systems, and H2 storage and distribution facilities. Part two then examines modern methods of characterization and analysis of hydrogen damage and part three focuses on the hydrogen degradation of various alloy classes
With its distinguished editors and international team of expert contributors, Volume 1 of Gaseous hydrogen embrittlement of materials in energy technologies is an invaluable reference tool for engineers, designers, materials scientists, and solid mechanicians working with safety-critical components fabricated from high performance materials required to operate in severe environments based on hydrogen. Impacted technologies include aerospace, petrochemical refining, gas transmission, power generation and transportation.
Contributor contact details Introduction Part I: The hydrogen embrittlement problem Chapter 1: Hydrogen production and containment Abstract: 1.1 Introduction 1.2 American Society of Mechanical Engineers (ASME) stationary vessels in hydrogen service 1.3 Department of Transportation (DOT) steel transport vessels 1.4 Fracture mechanics method for steel hydrogen vessel design 1.5 American Society of Mechanical Engineers (ASME) stationary composite vessels 1.6 Composite transport vessels 1.7 Hydrogen pipelines 1.8 Gaseous hydrogen leakage 1.9 Joint design and selection 1.10 American Society of Mechanical Engineers (ASME) code leak and pressure testing Chapter 2: Hydrogen-induced disbonding and embrittlement of steels used in petrochemical refining Abstract: 2.1 Introduction 2.2 Petrochemical refining 2.3 Problems during/after cooling of reactors 2.4 Effect of hydrogen content on mechanical properties 2.5 Conclusion Chapter 3: Assessing hydrogen embrittlement in automotive hydrogen tanks Abstract: 3.1 Introduction 3.2 Experimental details 3.3 Results and discussion 3.4 Conclusions and future trends Chapter 4: Gaseous hydrogen issues in nuclear waste disposal Abstract: 4.1 Introduction 4.2 Nature of nuclear wastes and their disposal environments 4.3 Gaseous hydrogen issues in the disposal of high activity wastes Chapter 5: Hydrogen embrittlement in nuclear power systems Abstract: 5.1 Introduction 5.2 Experimental methods 5.3 Environmental factors 5.4 Metallurgical effects 5.5 Conclusions 5.6 Acknowledgements Chapter 6: Standards and codes to control hydrogen-induced cracking in pressure vessels and pipes for hydrogen gas storage and transport Abstract: 6.1 Introduction 6.2 Basic code selected for pressure vessels 6.3 Code for piping and pipelines 6.4 Additional code requirements for high pressure hydrogen applications 6.5 Methods for calculating the design cyclic (fatigue) life 6.6 Example of crack growth in a high pressure hydrogen environment 6.7 Summary and conclusions Part II: Characterisation and analysis of hydrogen embrittlement Chapter 7: Fracture and fatigue test methods in hydrogen gas Abstract: 7.1 Introduction 7.2 General considerations for conducting tests in external hydrogen 7.3 Test methods 7.4 Conclusions 7.5 Acknowledgements Chapter 8: Mechanics of modern test methods and quantitative-accelerated testing for hydrogen embrittlement Abstract: 8.1 Introduction 8.2 General aspects of hydrogen embrittlement (HE) testing 8.3 Smooth specimens 8.4 Pre-cracked specimens – the fracture mechanics (FM) approach to stress corrosion cracking (SCC) 8.5 Limitations of the linear elastic fracture mechanics (FM) approach 8.6 Future trends 8.7 Conclusions Chapter 9: Metallographic and fractographic techniques for characterising and understanding hydrogen-assisted cracking of metals Abstract: 9.1 Introduction 9.2 Characterisation of microstructures and hydrogen distributions 9.3 Crack paths with respect to microstructure 9.4 Characterising fracture-surface appearance (and interpretation of features) 9.5 Determining fracture-surface crystallography 9.6 Characterising slip-distributions and strains around cracks 9.7 Determining the effects of solute hydrogen on dislocation activity 9.8 Determining the effects of adsorbed hydrogen on surfaces 9.9 In situ transmission electron microscopy (TEM) observations of fracture in thin foils and other TEM studies 9.10 ‘Critical’ experiments for determining mechanisms of hydrogen-assisted cracking (HAC 9.11 Proposed mechanisms of hydrogen-assisted cracking (HAC) 9.12 Conclusions 9.13 Acknowledgements Chapter 10: Fatigue crack initiation and fatigue life of metals exposed to hydrogen Abstract: 10.1 Introduction 10.2 Effect of hydrogen on total-life fatigue testing and fatigue crack growth (FCG) threshold stress intensity range 10.3 Mechanisms of fatigue crack initiation (FCI) 10.4 Conclusions 10.5 Future trends in total-life design of structural components Chapter 11: Effects of hydrogen on fatigue-crack propagation in steels Abstract: 11.1 Introduction 11.2 Materials and experimental methods 11.3 Effect of hydrogen on the fatigue behavior of martensitic SCM435 Cr–Mo steel 11.4 Effect of hydrogen on fatigue-crack growth behavior in austenitic stainless steels 11.5 Effects of hydrogen on fatigue behavior in lower-strength bainitic/ferritic/martensitic steels 11.6 Summary and conclusions 11.7 Acknowledgement 11.9 Appendix Part III: The hydrogen embrittlement of alloy classes Chapter 12: Hydrogen embrittlement of high strength steels Abstract: 12.1 Introduction 12.2 Microstructures of martensitic high strength steels 12.3 Effects of hydrogen on crack growth 12.4 Discussion of microstructural effects 12.5 Conclusions Chapter 13: Hydrogen trapping phenomena in martensitic steels Abstract: 13.1 Introduction 13.2 Hydrogen in the normal lattice of pure iron 13.3 Theoretical treatments for diffusion in a lattice containing trap sites 13.4 Experimental and simulation techniques for measurement of trapping parameters 13.5 Hydrogen trapping at lattice defects in martensitic steels 13.6 Design of nano-sized alloy carbides as beneficial trap sites to enhance resistance to hydrogen embrittlement 13.7 Conclusions Chapter 14: Hydrogen embrittlement of carbon steels and their welds Abstract: 14.1 Introduction 14.2 Hydrogen solubility and diffusivity in carbon steels 14.3 Mechanical properties of carbon steels and their welds in high pressure hydrogen 14.4 Important factors in hydrogen gas embrittlement 14.5 Hydrogen embrittlement mechanisms in low strength carbon steels 14.6 Future research needs 14.7 Conclusions 14.8 Sources of further information and advice Chapter 15: Hydrogen embrittlement of high strength, low alloy (HSLA) steels and their welds Abstract: 15.1 Introduction 15.2 The family of high strength, low alloy (HSLA) steels 15.3 The welding of high strength, low alloy (HSLA) steels 15.4 Mechanical effect of hydrogen on high strength, low alloy (HSLA) steels 15.5 Conclusions Chapter 16: Hydrogen embrittlement of stainless steels and their welds Abstract: 16.1 Introduction 16.2 Fundamentals of austenitic stainless steels 16.3 Hydrogen transport 16.4 Environment test methods 16.5 Models and mechanisms 16.6 Observations of hydrogen-assisted fracture 16.7 Trends in hydrogen-assisted fracture 16.8 Conclusions and future trends 16.9 Acknowledgments Chapter 17: Hydrogen embrittlement of nickel, cobalt and iron-based superalloys Abstract: 17.1 Introduction 17.2 Hydrogen transport properties in superalloys 17.3 Hydrogen gas effects on mechanical properties of superalloys 17.4 Important factors in hydrogen embrittlement 17.5 Future trends 17.6 Conclusions Chapter 18: Hydrogen effects in titanium alloys Abstract: 18.1 Introduction 18.2 Terminology, classification and properties of titanium alloys 18.3 Hydrogen embrittlement behavior in different classes of titanium alloys 18.4 Hydrogen trapping in titanium alloys 18.5 Positive effects in titanium alloys 18.6 Summary and conclusions Chapter 19: Hydrogen embrittlement of aluminum and aluminum-based alloys Abstract: 19.1 Introduction: scope and objective 19.2 Hydrogen interactions in Al alloy systems (experiment and modeling) 19.3 Gaseous hydrogen and hydrogen environment embrittlement (HEE) in Al-based alloys 19.4 Mechanisms of hydrogen-assisted cracking in Al-based systems 19.5 Improvement of the hydrogen resistant Al-base alloys based on metallurgical, surface engineering or environmental chemistry modifications 19.6 Needs, gaps and opportunities in Al-based systems 19.7 Future trends 19.8 Sources of further information and advice Chapter 20: Hydrogen-induced degradation of rubber seals Abstract: 20.1 Introduction 20.2 Example of cracking of a rubber O-ring used in a high pressure hydrogen storage vessel 20.3 Effect of filler on blister damage to rubber sealing materials in high pressure hydrogen gas 20.4 Influence of gaseous hydrogen on the degradation of a rubber sealing material 20.5 Testing of the durability of a rubber O-ring by using a high pressure hydrogen durability tester 20.6 Additional work required and future plans 20.7 Conclusions 20.8 Acknowledgement Index
Subject Areas: Alternative & renewable energy sources & technology [THX]
