The achievement of high quality in the design and construction of a multitude of products requires the evaluation of stresses and displacements caused by the temperature fields which change in time and space. This series of handbooks presents state-of-the-art papers, with the aim of stimulating interest in this field of research and to assist engineers in their everyday work. Examined in this second volume are: solutions of dynamical problems in plates, assessment of stress singularities, use of the Maysel's formula, probabilistic methods, micropolar theory, and low-cycle fatigue.
The achievement of high quality in the design and construction of a multitude of products requires the evaluation of stresses and displacements caused by the temperature fields which change in time and space. This series of handbooks presents state-of-the-art papers, with the aim of stimulating interest in this field of research and to assist engineers in their everyday work. Examined in this second volume are: solutions of dynamical problems in plates, assessment of stress singularities, use of the Maysel's formula, probabilistic methods, micropolar theory, and low-cycle fatigue.
Sprache
Verlagsort
Verlagsgruppe
Elsevier Science & Technology
Zielgruppe
Für höhere Schule und Studium
Für Beruf und Forschung
Maße
Höhe: 230 mm
Breite: 150 mm
ISBN-13
978-0-444-70046-9 (9780444700469)
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Schweitzer Klassifikation
Thermal Stresses in Plates - Dynamical Problems (T.R. Tauchert). Thermoelastic Theory for Plates. Solutions to Coupled Problems. Solutions to Uncoupled Problems. Anisotropic and Heterogeneous Plates. Additional Topics. Thermal Stress Singularities (H. Sekine). Basic Formulas of Two-Dimensional Theory of Thermoelasticity. Temperature Dislocations, Heat Sources, Edge Dislocations, and Concentrated Forces. Crack Problems. Flat Inclusion Problems. Thin Stiffener Problems. Appendices. Thermal Stress Analysis Based on Maysel's Formula (F. Ziegler, H. Irschik). General Theory. Maysels' Formula and Distributed Dummy Loads. Structural Applications of Maysel's Formula. Bending of Thin Plates. Thermoelastic Deformation of Thin Shells. Appendices. Probabilistic Methods in Thermal Stress Analysis (R.A. Heller, S. Thangjitham). Probabilistic and Statistical Preliminaries. Random Processes. Stress and Strength. Temperature Models. Random Temperature Input to a Semi-Infinite Slab. A Simple Stress-Strength Interference Problem. Random Thermal Stresses in a Layered Cylinder. Calculation of the Probability of Failure. Reliability of Brittle Materials. Reliability of a Proof-Loaded, Layered, Hollow Cylinder. Analysis of Orthotropic Materials. Micropolar Thermoelasticity (R.S. Dhaliwal, A. Singh). Basic Theorems. Displacement and Other Functions. Generalized Micropolar Thermoelasticity. Solutions of Specific Problems. Media with Microstructure and Micromorphic Media. Low-Cycle Thermal Fatigue (G.R. Halford). Historical Perspective. Thermal and Thermomechanical Fatigue - Unbalanced Deformation and Cracking Processes. Thermal Fatigue Resistance. Thermomechanical Fatigue (TMF). Bithermal Fatigue. Isothermal Life Prediction Models. Prediction of TMF Lives Using Idealized Isothermal Characteristics. Thermal Fatigue Life Predictions of Engineering Structural Components. Do's and Don'ts in Design Against Thermal Fatigue. References. Index.
