A Teaching Essay on Residual Stresses and Eigenstrains
Auteur : Korsunsky Alexander M.
Residual stresses are an important subject in materials science and engineering that has implications across disciplines, from quantum dots to human teeth, from aeroengines to automotive surface finishing. Although a number of monographs exist, no resource is available in the form of a book to serve as a good basis for teaching the fundamentals.
A Teaching Essay on Residual Stresses and Eigenstrains introduces eigenstrain methods as a powerful unified approach to residual stress modeling, measurement, and management. Starting with simple residual stress states, the key relationships are elucidated between deformation processes, inelastic strains (eigenstrains) these may introduce, and the resulting residual stress states. This book is written not only for the materials scientist, mechanical engineer, and student seeking to appreciate the origins of residual stress, but also for the more mature researcher and industrial engineer looking to improve their understanding of the eigenstrain approach to describing residual stress.
1. Introduction and Outline2. Elastic and Inelastic Deformation, and Residual Stress3. Simple Residual Stress Systems4. Inelastic Bending of Beams5. Plastic Yielding of Cylinders6. The Eigenstrain Theory of Residual Stress7. Dislocations8. Residual Stress ‘Measurement’9. Micro-Scale Methods of Residual Stress Evaluation10. The Inverse Eigenstrain Method of Residual Stress Reconstruction11. Eigenstrain Methods in Structural Integrity Analysis12. Conclusions and Outlook
Materials scientists; Chemical, electronic, and mechanical engineers, physicists, optics, communications technologists, MEMS, coatings, automotive, manufacturers, Late undergraduate / postgraduate / post-doctoral students
In the last two decades, Alexander Korsunsky has been the most active proponent of eigenstrain theory for the analysis of inelastic deformation and residual stresses in materials and components. He teaches widely across the world, and each year gives several keynote and plenary lectures at major international conferences on engineering and materials. The broader context of Prof Korsunsky’s research interests concern improving the understanding of integrity and reliability of engineered and natural structures and systems, from high-performance metallic alloys to polycrystalline ceramics to natural hard tissues, such as human dentin and seashell nacre. He has co-authored books on fracture mechanics and elasticity and has published over 300 papers in scholarly periodicals on subjects ranging from multi-modal microscopy, neutron and synchrotron X-ray analysis, contact mechanics and structural integrity to micro-cantilever bio-sensors, size effects, and scaling transitions. Prof Korsunsky plays a leading role in the development of large-scale research facilities in the UK and Europe. He has chaired the Science Advisory Committee at Diamond Light Source, and is member of UK delegation to ESRF Council. His activities expand the range of applications of large-scale science to problems in real engineering practice.
Prof Korsunsky’s research has received support from EPSRC and STFC (major UK Research Councils), the European Commission, the Royal Society, R
- Provides a unified basis for understanding the fundamentals of residual stress origins and consequences
- Introduces a classification of the most important residual stress states and their efficient description, as well as discussing measurement approaches, their limitations, and uses
- Approaches the nature and application of eigenstrain methods in a systematic way to describe residual stress fields
Date de parution : 06-2017
Ouvrage de 212 p.
19x23.3 cm
Thème d’A Teaching Essay on Residual Stresses and Eigenstrains :
Mots-clés :
Autofrettage; Beam bending; Bragg edge strain tomography; Compatibility; Continuum plasticity; Current state modeling; Diffraction; Direct and inverse problems of eigenstrain; Discrete dislocation dynamics; Dislocation dipoles; Dislocation; EBSD; Eigenstrain; Elasticity; Eshelby ellipsoidal inclusions; FIB-DIC micro-ring-core; Focused ion beam; Frank-Read sources; Fretting; Generalized Hooke's law; Hardening; Ideal plasticity; Inelastic beam bending; Inverse problem of eigenstrain; Inverse problem; Lam�Laue; Least squares; Macrostress; Masing model; Microstress; Nanoscale residual stress; Neutron Bragg edge; Nuclei of strain; Plastic strain; problem; Process modeling; Quenching; Ramberg-Osgood description; Residual stress; Rich tomography; Shot peening; Spectroscopy; Strain decomposition; Strain relief; Strain tomography; Stress measurement; Voigt (contracted) notation; Voigt and Reuss composites; Welds; XRD