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Ceramics [[electronic resource] ] : Mechanical Properties, Failure Behaviour, Materials Selection / / by Dietrich Munz, Theo Fett
| Ceramics [[electronic resource] ] : Mechanical Properties, Failure Behaviour, Materials Selection / / by Dietrich Munz, Theo Fett |
| Autore | Munz Dietrich |
| Edizione | [1st ed. 1999.] |
| Pubbl/distr/stampa | Berlin, Heidelberg : , : Springer Berlin Heidelberg : , : Imprint : Springer, , 1999 |
| Descrizione fisica | 1 online resource (X, 299 p.) |
| Disciplina | 620.1/4 |
| Collana | Springer Series in Materials Science |
| Soggetto topico |
Industrial engineering
Production engineering Materials science Mechanics Mechanics, Applied Industrial and Production Engineering Materials Science, general Characterization and Evaluation of Materials Theoretical and Applied Mechanics |
| ISBN | 3-642-58407-1 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | 1 Overview and Basic Properties -- 1.1 General Behaviour -- 1.2 Overview of Ceramic Materials -- 1.3 Fields of Application -- 2 Physical Properties -- 2.1 Thermal Expansion Coefficient -- 2.2 Thermal Conductivity -- 2.3 Electrical Conductivity -- 2.4 Specific Heat -- 2.5 Density -- 2.6 Elastic Constants -- 3 Fracture Mechanics -- 3.1 Fundamentals -- 3.2 Experimental Methods for the Determination of the Mode-I Fracture Toughness KIc -- 3.3 Experimental Methods for the Determination of Mode-II and Mixed-Mode Fracture Toughness -- 3.4 Mixed-Mode Criteria and Experimental Results -- 4 R-Curve Behaviour -- 4.1 Experimental Observation -- 4.2 Determination of R-Curves -- 4.3 Reasons for R-Curve Behaviour -- 4.4 Influence of R-Curves on Strength -- 4.5 Computation of R-Curves -- 4.6 Determination of Bridging Stresses from Crack Profiles -- 5 Subcritical Crack Growth -- 5.1 Basic Relations -- 5.2 Computation of Lifetimes -- 5.3 Methods of Determining Subcritical Crack Growth -- 5.4 Influence of R-Curve Behaviour on Subcritical Crack Growth -- 5.5 Some Theoretical Considerations on Subcritical Crack Growth -- 6 Cyclic Fatigue -- 6.1 Representation of Cyclic Fatigue Results -- 6.2 Proof of a Cyclic Effect -- 6.3 Methods for the Determination of da/dN-?K Curves -- 6.4 Effect of R-Ratio -- 6.5 Theoretical Considerations -- 6.6 Differences Between Micro- and Macrocracks -- 7 Determination of Strength -- 7.1 Measurement of Tensile Strength -- 7.2 Measurement of Compressive Strength -- 8 Scatter of Mechanical Properties -- 8.1 Principal Behaviour -- 8.2 Determination of Weibull Parameters -- 8.3 The Size Effect -- 8.4 Scatter of Lifetimes -- 8.5 Some Specific Problems -- 9 Proof Test Procedure -- 9.1 Proof Test Without Subcritical Crack Growth -- 9.2 Proof Test Including Subcritical Crack Growth -- 9.3 Problems in Proof Tests -- 10 Multiaxial Failure Criteria -- 10.1 Representation in Multiaxiality Diagrams -- 10.2 Global Multiaxiality Criteria -- 10.3 Defect Models -- 10.4 Experimental Methods -- 10.5 Experimental Results -- 11 Thermal Shock Behaviour -- 11.1 Thermal Stresses -- 11.2 Measurement of Thermal Shock Sensitivity -- 11.3 Fracture Mechanical Treatment of Thermal Shock -- 11.4 Thermal Shock Parameters -- 11.5 Size Effect in Thermal Shock -- 11.6 Thermal Fatigue -- 12 High-Temperature Behaviour -- 12.1 Creep Deformation -- 12.2 Failure in the Creep Range -- 12.3 Creep Crack Growth -- 13 Plasticity -- 13.1 Plasticity During Contact Loading -- 13.2 Plasticity During Surface Grinding -- 13.3 Plasticity by Phase Transformation in Zirconia -- 13.4 Plasticity by Domain Switching in Piezoelectric Ceramics -- 13.5 Measurement of Plastic Deformations in Bending Tests -- 13.6 Time-Dependent Plasticity Effects -- A.1 Rectangular Bar -- A.2 Comact-Tension (CT) Specimen -- A.3 Round Compact Tension (RCT) Specimen -- A.4 Double-Cantilever-Beam Specimen (DCB) -- A.5 Weight Function for Chevron-Notched Bending Bars -- A.6 Specimens for Mixed-Mode Tests. |
| Record Nr. | UNINA-9910480837003321 |
Munz Dietrich
|
||
| Berlin, Heidelberg : , : Springer Berlin Heidelberg : , : Imprint : Springer, , 1999 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Ceramics [[electronic resource] ] : Mechanical Properties, Failure Behaviour, Materials Selection / / by Dietrich Munz, Theo Fett
| Ceramics [[electronic resource] ] : Mechanical Properties, Failure Behaviour, Materials Selection / / by Dietrich Munz, Theo Fett |
| Autore | Munz Dietrich |
| Edizione | [1st ed. 1999.] |
| Pubbl/distr/stampa | Berlin, Heidelberg : , : Springer Berlin Heidelberg : , : Imprint : Springer, , 1999 |
| Descrizione fisica | 1 online resource (X, 299 p.) |
| Disciplina | 620.1/4 |
| Collana | Springer Series in Materials Science |
| Soggetto topico |
Industrial engineering
Production engineering Materials science Mechanics Mechanics, Applied Industrial and Production Engineering Materials Science, general Characterization and Evaluation of Materials Theoretical and Applied Mechanics |
| ISBN | 3-642-58407-1 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | 1 Overview and Basic Properties -- 1.1 General Behaviour -- 1.2 Overview of Ceramic Materials -- 1.3 Fields of Application -- 2 Physical Properties -- 2.1 Thermal Expansion Coefficient -- 2.2 Thermal Conductivity -- 2.3 Electrical Conductivity -- 2.4 Specific Heat -- 2.5 Density -- 2.6 Elastic Constants -- 3 Fracture Mechanics -- 3.1 Fundamentals -- 3.2 Experimental Methods for the Determination of the Mode-I Fracture Toughness KIc -- 3.3 Experimental Methods for the Determination of Mode-II and Mixed-Mode Fracture Toughness -- 3.4 Mixed-Mode Criteria and Experimental Results -- 4 R-Curve Behaviour -- 4.1 Experimental Observation -- 4.2 Determination of R-Curves -- 4.3 Reasons for R-Curve Behaviour -- 4.4 Influence of R-Curves on Strength -- 4.5 Computation of R-Curves -- 4.6 Determination of Bridging Stresses from Crack Profiles -- 5 Subcritical Crack Growth -- 5.1 Basic Relations -- 5.2 Computation of Lifetimes -- 5.3 Methods of Determining Subcritical Crack Growth -- 5.4 Influence of R-Curve Behaviour on Subcritical Crack Growth -- 5.5 Some Theoretical Considerations on Subcritical Crack Growth -- 6 Cyclic Fatigue -- 6.1 Representation of Cyclic Fatigue Results -- 6.2 Proof of a Cyclic Effect -- 6.3 Methods for the Determination of da/dN-?K Curves -- 6.4 Effect of R-Ratio -- 6.5 Theoretical Considerations -- 6.6 Differences Between Micro- and Macrocracks -- 7 Determination of Strength -- 7.1 Measurement of Tensile Strength -- 7.2 Measurement of Compressive Strength -- 8 Scatter of Mechanical Properties -- 8.1 Principal Behaviour -- 8.2 Determination of Weibull Parameters -- 8.3 The Size Effect -- 8.4 Scatter of Lifetimes -- 8.5 Some Specific Problems -- 9 Proof Test Procedure -- 9.1 Proof Test Without Subcritical Crack Growth -- 9.2 Proof Test Including Subcritical Crack Growth -- 9.3 Problems in Proof Tests -- 10 Multiaxial Failure Criteria -- 10.1 Representation in Multiaxiality Diagrams -- 10.2 Global Multiaxiality Criteria -- 10.3 Defect Models -- 10.4 Experimental Methods -- 10.5 Experimental Results -- 11 Thermal Shock Behaviour -- 11.1 Thermal Stresses -- 11.2 Measurement of Thermal Shock Sensitivity -- 11.3 Fracture Mechanical Treatment of Thermal Shock -- 11.4 Thermal Shock Parameters -- 11.5 Size Effect in Thermal Shock -- 11.6 Thermal Fatigue -- 12 High-Temperature Behaviour -- 12.1 Creep Deformation -- 12.2 Failure in the Creep Range -- 12.3 Creep Crack Growth -- 13 Plasticity -- 13.1 Plasticity During Contact Loading -- 13.2 Plasticity During Surface Grinding -- 13.3 Plasticity by Phase Transformation in Zirconia -- 13.4 Plasticity by Domain Switching in Piezoelectric Ceramics -- 13.5 Measurement of Plastic Deformations in Bending Tests -- 13.6 Time-Dependent Plasticity Effects -- A.1 Rectangular Bar -- A.2 Comact-Tension (CT) Specimen -- A.3 Round Compact Tension (RCT) Specimen -- A.4 Double-Cantilever-Beam Specimen (DCB) -- A.5 Weight Function for Chevron-Notched Bending Bars -- A.6 Specimens for Mixed-Mode Tests. |
| Record Nr. | UNINA-9910792493803321 |
|
Munz Dietrich
|
||
| Berlin, Heidelberg : , : Springer Berlin Heidelberg : , : Imprint : Springer, , 1999 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Ceramics : Mechanical Properties, Failure Behaviour, Materials Selection / / by Dietrich Munz, Theo Fett
| Ceramics : Mechanical Properties, Failure Behaviour, Materials Selection / / by Dietrich Munz, Theo Fett |
| Autore | Munz Dietrich |
| Edizione | [1st ed. 1999.] |
| Pubbl/distr/stampa | Berlin, Heidelberg : , : Springer Berlin Heidelberg : , : Imprint : Springer, , 1999 |
| Descrizione fisica | 1 online resource (X, 299 p.) |
| Disciplina | 620.1/4 |
| Collana | Springer Series in Materials Science |
| Soggetto topico |
Industrial engineering
Production engineering Materials science Mechanics Mechanics, Applied Industrial and Production Engineering Materials Science, general Characterization and Evaluation of Materials Theoretical and Applied Mechanics |
| ISBN | 3-642-58407-1 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | 1 Overview and Basic Properties -- 1.1 General Behaviour -- 1.2 Overview of Ceramic Materials -- 1.3 Fields of Application -- 2 Physical Properties -- 2.1 Thermal Expansion Coefficient -- 2.2 Thermal Conductivity -- 2.3 Electrical Conductivity -- 2.4 Specific Heat -- 2.5 Density -- 2.6 Elastic Constants -- 3 Fracture Mechanics -- 3.1 Fundamentals -- 3.2 Experimental Methods for the Determination of the Mode-I Fracture Toughness KIc -- 3.3 Experimental Methods for the Determination of Mode-II and Mixed-Mode Fracture Toughness -- 3.4 Mixed-Mode Criteria and Experimental Results -- 4 R-Curve Behaviour -- 4.1 Experimental Observation -- 4.2 Determination of R-Curves -- 4.3 Reasons for R-Curve Behaviour -- 4.4 Influence of R-Curves on Strength -- 4.5 Computation of R-Curves -- 4.6 Determination of Bridging Stresses from Crack Profiles -- 5 Subcritical Crack Growth -- 5.1 Basic Relations -- 5.2 Computation of Lifetimes -- 5.3 Methods of Determining Subcritical Crack Growth -- 5.4 Influence of R-Curve Behaviour on Subcritical Crack Growth -- 5.5 Some Theoretical Considerations on Subcritical Crack Growth -- 6 Cyclic Fatigue -- 6.1 Representation of Cyclic Fatigue Results -- 6.2 Proof of a Cyclic Effect -- 6.3 Methods for the Determination of da/dN-?K Curves -- 6.4 Effect of R-Ratio -- 6.5 Theoretical Considerations -- 6.6 Differences Between Micro- and Macrocracks -- 7 Determination of Strength -- 7.1 Measurement of Tensile Strength -- 7.2 Measurement of Compressive Strength -- 8 Scatter of Mechanical Properties -- 8.1 Principal Behaviour -- 8.2 Determination of Weibull Parameters -- 8.3 The Size Effect -- 8.4 Scatter of Lifetimes -- 8.5 Some Specific Problems -- 9 Proof Test Procedure -- 9.1 Proof Test Without Subcritical Crack Growth -- 9.2 Proof Test Including Subcritical Crack Growth -- 9.3 Problems in Proof Tests -- 10 Multiaxial Failure Criteria -- 10.1 Representation in Multiaxiality Diagrams -- 10.2 Global Multiaxiality Criteria -- 10.3 Defect Models -- 10.4 Experimental Methods -- 10.5 Experimental Results -- 11 Thermal Shock Behaviour -- 11.1 Thermal Stresses -- 11.2 Measurement of Thermal Shock Sensitivity -- 11.3 Fracture Mechanical Treatment of Thermal Shock -- 11.4 Thermal Shock Parameters -- 11.5 Size Effect in Thermal Shock -- 11.6 Thermal Fatigue -- 12 High-Temperature Behaviour -- 12.1 Creep Deformation -- 12.2 Failure in the Creep Range -- 12.3 Creep Crack Growth -- 13 Plasticity -- 13.1 Plasticity During Contact Loading -- 13.2 Plasticity During Surface Grinding -- 13.3 Plasticity by Phase Transformation in Zirconia -- 13.4 Plasticity by Domain Switching in Piezoelectric Ceramics -- 13.5 Measurement of Plastic Deformations in Bending Tests -- 13.6 Time-Dependent Plasticity Effects -- A.1 Rectangular Bar -- A.2 Comact-Tension (CT) Specimen -- A.3 Round Compact Tension (RCT) Specimen -- A.4 Double-Cantilever-Beam Specimen (DCB) -- A.5 Weight Function for Chevron-Notched Bending Bars -- A.6 Specimens for Mixed-Mode Tests. |
| Record Nr. | UNINA-9910817423703321 |
|
Munz Dietrich
|
||
| Berlin, Heidelberg : , : Springer Berlin Heidelberg : , : Imprint : Springer, , 1999 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||