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Preface | ||
Introduction | ||
Pt. I | Light Metal PM-Aluminium- and Titanium-Base Alloys | |
1 | Structure and Properties of P/M Al-Alloys for High-Temperature Application | 3 |
2 | Creep Behaviour and Microstructure of Dispersion-Strengthened PM-Aluminium-Materials at Elevated Temperatures | 18 |
3 | High-Temperature Fatigue Behaviour and Microstructure of a Dispersoid-Strengthened and SiC-Reinforced Aluminium Alloy | 34 |
4 | Fatigue Behaviour of Dispersion-Strengthened Aluminium Materials between 293 and 773 K | 50 |
5 | On the Microstructural Features Governing the High-Temperature Deformation Behaviour of the Silicon-Bearing Near-[alpha] Titanium Alloy IMI 834 | 62 |
6 | Processing Window and Mechanical Behaviour for Fine-Grained [beta]-Structure of the Near-[alpha] Titanium Alloy TIMETAL 1100 | 79 |
7 | Correlation between Microstructure and High-Temperature Plasticity - Superplasticity and Creep - of Particle-Strengthened [alpha]-Ti/Ti[subscript 2]Co Alloys | 95 |
8 | Influence of Microstructure on the High-Temperature Fatigue Behaviour of the Titanium Alloy IMI 834 | 110 |
9 | Influence of Silicide Precipitates on Microstructure and Fatigue of TIMETAL 1100 | 122 |
10 | Influence of Loading Frequency on Fatigue Life of TIMETAL 1100 | 134 |
11 | Mean Stress Sensitivity during Fatigue of the Near-[alpha] Titanium Alloy TIMETAL 1100. Effects of Test Temperature | 144 |
12 | Load Type Influences on the High-Temperature Creep-Fatigue Behaviour of the Titanium Alloy IMI 834 and Creep-Fatigue Life Prediction | 157 |
Pt. II | Ferritic Chromium and Austenitic Alloy 800 Steels | |
13 | Microstructure-Based Modelling of the Long-Term Monotonic and Cyclic Creep of the Martensitic Steel X 20(22) CrMoV 12 1 | 179 |
14 | A Microstructural Model to Predict the Multiaxial Creep and Damage in 12 Cr Steel Grade at 550[degree]C | 192 |
15 | A Multiaxial Model for the Evolution of the Microstructure and for the Mechanical Behaviour of a 12% Chromium Steel under Creep Conditions | 206 |
16 | Cyclic Deformation Behaviour and Microstructural Changes of the 12% Chromium Steel X22CrMoV121 | 222 |
17 | Influence of the Maximum Cycle Temperature and the Dwell Time on the Thermal-Mechanical Fatigue Behaviour of a 12% Chromium Steel | 235 |
18 | Microstructure Characterization of the Ferritic Steel X22CrMoV 12 1 after Isothermal and Thermal-Mechanical Fatigue Loading | 248 |
19 | Propagation of Short Cracks in Alloy 800HT and in the Steel 22CrMoV12 - 1 at High Temperature under Biaxial Fatigue | 261 |
20 | Flow Behaviour and Microstructure of the Heat-Resistant Steels X20CrMoV12.1 and X5NiCrTiAl32.20 (Alloy 800) | 272 |
21 | Microstructure and Creep Behaviour of Alloy 800HT | 291 |
22 | Mechanical Behaviour and Microstructural Evolution of Alloy 800H under Biaxial Cyclic Loading | 306 |
23 | Grain-Boundary Self-Diffusion of Alloy 800 and Influence of S, P and C on Grain-Boundary Diffusion and Creep Cavity Formation in Alloy 800 | 320 |
Pt. III | (Monocrystalline) Nickel-Base Superalloys | |
24 | Elasticity of High-Temperature Alloys | 337 |
25 | Investigations on TEM Foil Preparation and Microstructure of the Superalloys N18 and CMSX-4 | 356 |
26 | Identification of Slip Systems and CRSS Anisotropy of a Monocrystalline Nickel-Base Superalloy in the Temperature Range of the Yield Strength Maximum | 370 |
27 | Mechanical and Microstructural Investigations of Processes Governing Annealing and Shear Creep Anisotropy of the Single Crystal Superalloy CMSX-4 at Temperatures above 1000[degree]C | 384 |
28 | Phase-Specific Strains and Stresses in [gamma]'-Hardened Nickel-Base Superalloys After High-Temperature Deformation Determined by High-Resolution X-Ray and Neutron Diffraction Techniques | 397 |
29 | Deformation Mechanisms at 1000[degree]C in Single Crystalline Nickel-Base Superalloys after Multiaxial Loading | 411 |
30 | Influence of Directional Coarsening on the Isothermal High-Temperature Fatigue Behaviour of the Monocrystalline Nickel-Base Superalloys CMSX-6 and CMSX-4 | 425 |
31 | Influence of Cellular Recrystallization on the Fatigue Behaviour of Single Crystal Ni-Based Superalloys | 441 |
32 | Influence of Microstructure on the Mechanical Properties of U 720 LI | 454 |
Pt. IV | Nickel- and Iron-Base ODS Superalloys | |
33 | LCF and Microstructure of the ODS Nickel-Base Superalloy PM 1000 at 1123 K | 465 |
34 | Influence of Thermomechanical Treatment on Grain Growth in the [gamma]'-Rich Nickel-Base ODS Superalloy PM3030 | 479 |
35 | High-Temperature Creep of the Iron-Base ODS Alloy PM 2000 and its Modelling | 495 |
36 | Micromechanical Analysis of the Creep Behaviour of Iron-Base Superalloys | 509 |
37 | Influence of Grain, Dislocation and Phase Structure on the Long-Term Deformation Behaviour of Fe-base ODS Alloys in the Creep Regime | 530 |
38 | Influence of Microstructural Parameters on the Deformation and Failure Behaviour of the ODS Alloy PM 2000 under Creep and Creep-Fatigue Loading | 547 |
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Add Microstructure and Mechanical Properties of Metallic High Temperature Material, This book presents the results of the Priority Programme Microstructure and Mechanical Properties of Metallic High-Temperature Materials. The programme has been supported by the Deutsche Forschungsgemeinschaft (DFG) over a period of 6 years from 1991 ti, Microstructure and Mechanical Properties of Metallic High Temperature Material to the inventory that you are selling on WonderClubX
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Add Microstructure and Mechanical Properties of Metallic High Temperature Material, This book presents the results of the Priority Programme Microstructure and Mechanical Properties of Metallic High-Temperature Materials. The programme has been supported by the Deutsche Forschungsgemeinschaft (DFG) over a period of 6 years from 1991 ti, Microstructure and Mechanical Properties of Metallic High Temperature Material to your collection on WonderClub |