Abstract
To raise the efficiency of thermal power plants, operation temperature and pressure must be increased by improving the creep performance of materials such as martensitic Cr-steels. To understand the underlying mechanisms of degradation, physical creep modelling provides a detailed and profound insight into microstructural processes. For such a physically based dislocation creep model, it is demonstrated that based on a parameter set found for one experimental creep curve, numerous creep curves on different stress levels can be simulated without any additional experimental data. These simulation results are then used for constructing a TTR diagram of P92. We succeeded in extrapolating rupture times for variations in both applied stress and temperature. In all cases, microstructural evolution of the simulated material is considered, including dislocation density, subgrain size and precipitates. The obtained …
| Original language | English |
|---|---|
| Pages (from-to) | 161-166 |
| Number of pages | 6 |
| Journal | Materials at High Temperatures |
| Volume | 39 |
| DOIs | |
| Publication status | Published - Feb 2022 |
Fields of science
- 203 Mechanical Engineering
- 203007 Strength of materials
- 203024 Thermodynamics
- 203034 Continuum mechanics
- 211103 Physical metallurgy
- 211105 Nonferrous metallurgy
- 101014 Numerical mathematics
- 101028 Mathematical modelling
- 102001 Artificial intelligence
- 102022 Software development
- 103006 Chemical physics
- 103018 Materials physics
- 103042 Electron microscopy
- 105113 Crystallography
- 203002 Endurance strength
- 203013 Mechanical engineering
- 203037 Computational engineering
- 205019 Material sciences
- 211101 Iron and steel metallurgy
- 103009 Solid state physics
- 103043 Computational physics
JKU Focus areas
- Digital Transformation
- Sustainable Development: Responsible Technologies and Management