mechanics and multiscale modeling for nuclear industry · 2015. 3. 18. · iitk-igcar cell...
TRANSCRIPT
Continuum Damage Mechanics
Dyanamics of a subassembly
Thermal Ratcheting
Dynamic Fracture Toughness
Creep Deformation and Damage
Parametric Instability
of Fluid Filled Concentric Shells
Micromechanics-based
Macroscopic Plasticity Model
Damage at High Temperature and High Strain Rates
Ballooning of Fuel Clads
Coolant Mixing Visualization
Multi-Phase Convective Transport
Stability of a Nuclear
Mineral Sensor
Shear Banding in Alloy D9
Contact Details:
Indian Institute of Technology Kanpur, Kanpur- 208016
Instabilities in Natural
Convection
Parametric Instabilities in
thin-walled vessel
Thermal Striping
Wetting of Liquid Sodium
Prof. K. Muralidhar,Department of Mechanical EngineeringIITK-IGCAR Cell
Mechanics and Multiscale Modeling for Nuclear Industry
Mechanics aims to understand, follow, and predict macroscopic parameters of mechanical systems spread across a wide range of length scales – from cellular machines to space stations, and time scales – from impact duration to the Solar System’s forma-tion time.
Advanced material processing is making it possible to design materials tailored to speci�c needs. Knowledge of their micro-mechanics is essential for design. Multiscale material modeling attempts to relate macroscopic material response to its mi-crostructure.
IIT Kanpur has expertise in multiscale material modeling, sharing a robust relationship with a strong tradition in mechanics, making us advantageously placed for futuristic research.This is the basis of the collaboration of the Indira Gandhi Center for Atomic Research (IGCAR), Kalpakkam and IIT Kanpur on research related to indigenous design and development of Fast Breeder Reactors (FBR).