| Vorliegende Sprache |
eng |
| Hinweise auf parallele Ausgaben |
271026723 Buchausg. u.d.T.: ‡Rösler, Joachim, 1959 - : Mechanical behaviour of engineering materials |
| ISBN |
978-3-540-73446-8 |
| Name |
Rösler, Joachim |
| Bäker, Martin |
| ANZEIGE DER KETTE |
Bäker, Martin |
| Name |
Harders, Harald |
| T I T E L |
Mechanical Behaviour of Engineering Materials |
| Zusatz zum Titel |
Metals, Ceramics, Polymers, and Composites |
| Verlagsort |
Berlin, Heidelberg |
| Verlag |
Springer-Verlag Berlin Heidelberg |
| Erscheinungsjahr |
2007 |
| 2007 |
| Umfang |
Online-Ressource (digital) |
| Reihe |
SpringerLink. Bücher |
| Notiz / Fußnoten |
Includes bibliographical references (p. [485]-491) and index |
| Weiterer Inhalt |
""Preface""; ""Contents""; ""1 The structure of materials""; ""1.1 Atomic structure and the chemical bond""; ""1.2 Metals""; ""1.3 Ceramics""; ""1.4 Polymers""; ""2 Elasticity""; ""2.1 Deformation modes""; ""2.2 Stress and strain""; ""2.3 Atomic interactions""; ""2.4 Hooke s law""; ""2.5 Isotropy and anisotropy of macroscopic components""; ""2.6 Temperature dependence of Young's modulus""; ""3 Plasticity and failure""; ""3.1 Nominal and true strain""; ""3.2 Stress-strain diagrams""; ""3.3 Plasticity theory""; ""3.4 Hardness""; ""3.5 Material failure""; ""4 Notches"". ""4.1 Stress concentration factor""""4.2 Neuber's rule""; ""4.3 Tensile testing of notched specimens""; ""5 Fracture mechanics""; ""5.1 Introduction to fracture mechanics""; ""5.2 Linear-elastic fracture mechanics""; ""5.3 Elastic-plastic fracture mechanics""; ""6 Mechanical behaviour of metals""; ""6.1 Theoretical strength""; ""6.2 Dislocations""; ""6.3 Overcoming obstacles""; ""6.4 Strengthening mechanisms""; ""6.5 Mechanical twinning""; ""7 Mechanical behaviour of ceramics""; ""7.1 Manufacturing ceramics""; ""7.2 Mechanisms of crack propagation""; ""7.3 Statistical fracture mechanics"". ""7.4 Proof test""""7.5 Strengthening ceramics""; ""8 Mechanical behaviour of polymers""; ""8.1 Physical properties of polymers""; ""8.2 Time-dependent deformation of polymers""; ""8.3 Elastic properties of polymers""; ""8.4 Plastic behaviour""; ""8.5 Increasing the thermal stability""; ""8.6 Increasing strength and stiffness""; ""8.7 Increasing the ductility""; ""8.8 Environmental effects""; ""9 Mechanical behaviour of fibre reinforced composites""; ""9.1 Strengthening methods""; ""9.2 Elasticity of fibre composites""; ""9.3 Plasticity and fracture of composites"". ""9.4 Examples of composites""""10 Fatigue""; ""10.1 Types of loads""; ""10.2 Fatigue failure of metals""; ""10.3 Fatigue of ceramics""; ""10.4 Fatigue of polymers""; ""10.5 Fatigue of fibre composites""; ""10.6 Phenomenological description of the fatigue strength""; ""10.7 Fatigue of notched specimens""; ""11 Creep""; ""11.1 Phenomenology of creep""; ""11.2 Creep mechanisms""; ""11.3 Creep fracture""; ""11.4 Increasing the creep resistance""; ""12 Exercises""; ""Exercise 1: Packing density of crystals""; ""Exercise 2: Macromolecules""; ""Exercise 3: Interaction between two atoms"". ""Exercise 4: Bulk modulus""""Exercise 5: Relation between the elastic constants""; ""Exercise 6: Candy catapult""; ""Exercise 7: True strain""; ""Exercise 8: Interest calculation""; ""Exercise 9: Large deformations""; ""Exercise 10: Yield criteria""; ""Exercise 11: Yield criteria of polymers""; ""Exercise 12: Design of a notched shaft""; ""Exercise 13: Estimating the fracture toughness KIc""; ""Exercise 14: Determination of the fracture toughness KIc""; ""Exercise 15: Static design of a tube""; ""Exercise 16: Theoretical strength""; ""Exercise 17: Estimating the dislocation density"". ""Exercise 18: Thermally activated dislocation generation"" |
| Titelhinweis |
Buchausg. u.d.T.: ‡Rösler, Joachim, 1959 - : Mechanical behaviour of engineering materials |
| ISBN |
ISBN 978-3-540-73448-2 |
| Klassifikation |
TG |
| TEC009070 |
| TEC021000 |
| TGMD |
| SCI096000 |
| 620.1 |
| 620 |
| 531 |
| 620 |
| TA405-409.3 |
| QA808.2 |
| UQ 8025 |
| ZM 3200 |
| Kurzbeschreibung |
The structure of materials -- Elasticity -- Plasticity and failure -- Notches -- Fracture mechanics -- Mechanical behaviour of metals -- Mechanical behaviour of ceramics -- Mechanical behaviour of polymers -- Mechanical behaviour of fibre reinforced composites -- Fatigue -- Creep -- Exercises -- Solutions. |
| 2. Kurzbeschreibung |
How do engineering materials deform when bearing mechanical loads? To answer this crucial question, the book bridges the gap between continuum mechanics and materials science. The different kinds of material deformation (elasticity, plasticity, fracture, creep, fatigue) are explained in detail. The book also discusses the physical processes occurring during the deformation of all classes of engineering materials (metals, ceramics, polymers, and composites) and shows how these materials can be strengthened to meet the design requirements. It provides the knowledge needed in selecting the appropriate engineering material for a certain design problem. The reader will thus learn how to critically employ design rules and thus to avoid failure of mechanical components. ‘Mechanical Behaviour of Engineering Materials’ is both a valuable textbook and a useful reference for graduate students and practising engineers. |
| 1. Schlagwortkette |
Werkstoff |
| Mechanische Eigenschaft |
| 1. Schlagwortkette ANZEIGE DER KETTE |
Werkstoff -- Mechanische Eigenschaft |
| 2. Schlagwortkette |
Werkstoff |
| Mechanische Eigenschaft |
| ANZEIGE DER KETTE |
Werkstoff -- Mechanische Eigenschaft |
| SWB-Titel-Idn |
276337085 |
| Signatur |
Springer E-Book |
| Bemerkungen |
Elektronischer Volltext - Campuslizenz |
| Elektronische Adresse |
$uhttp://dx.doi.org/10.1007/978-3-540-73448-2 |
| Internetseite / Link |
Volltext |
| Siehe auch |
Volltext |
| Siehe auch |
Cover |
